ライフサイエンスコーパス: microelectrode

1 rent from that of a traditional carbon-fiber microelectrode.

2 and patients with CF was measured with a pH microelectrode.

3 ay and dopamine dynamics from a carbon-fiber microelectrode.

4 tween a counter electrode and a working disk microelectrode.

5 cular layer self-assembled on a tapered gold microelectrode.

6 toelectrocatalytically evolved oxygen at the microelectrode.

7 ions using a convective condition and a gold microelectrode.

8 captured at the surface of a nanostructured microelectrode.

9 p drinking water storage tank sediment using microelectrodes.

10 easuring its concentration using needle-type microelectrodes.

11 te, and nitrate profiles were acquired using microelectrodes.

12 voltammetry (FSCV) coupled with carbon-fiber microelectrodes.

13 om whole blood was trapped by the paper with microelectrodes.

14 stranded DNA probe oligomers on cleaned gold microelectrodes.

15 ice on microporous paper with patterned gold microelectrodes.

16 electrical stimulation via 100 mum-diameter microelectrodes.

17 ing cylindrical, Nafion-coated, carbon-fiber microelectrodes.

18 ectric fields applied through interdigitated microelectrodes.

19 ation in explant media was measured by using microelectrodes.

20 dation of superoxide on polymer covered gold microelectrodes.

21 oding than combining a much larger number of microelectrodes.

22 rrent (ac) waveform to electrically polarize microelectrodes.

23 ofluidic outlets using only a single pair of microelectrodes.

24 rodes and nanotip conical-shape carbon fiber microelectrodes.

25 vironments inside ACPs were quantified using microelectrodes.

26 ing PEDOT:PSS and platinum black on wrinkled microelectrodes.

27 of awake monkeys implanted with an array of microelectrodes.

28 acquiring data from 16 rectangularly shaped microelectrodes (20 x 3.5 mum(2)) separated by 200 mum g

29 rmed this task as we recorded from implanted microelectrodes, allowing us to compare the human neuron

30 individual granule release with carbon-fiber microelectrode amperometry.

31 in local field potential (LFP; obtained from microelectrodes), analogous characterization has not bee

32 de arrays, Interdigitated electrodes, curved microelectrode and 3D electrode orientations and give re

33 sent a robust technology of softening neural microelectrode and demonstrate its recording performance

34 n carrier in a liquid membrane ion-selective microelectrode and show the MC3-ISM has a linear Nernsti

35 mparable with those measured by carbon fiber microelectrodes and allowed to identify three different

36 designed a customized array containing both microelectrodes and ECoG electrodes to simultaneously ma

37 , we implanted customized arrays having both microelectrodes and electrocorticogram (ECoG) electrodes

38 nsors platform containing eight gold working microelectrodes and integrated reference and counter ele

39 multiunit firing and high frequency LFP from microelectrodes and macroelectrodes during ictal dischar

40 In this study, we used microelectrodes and macroelectrodes in surgical epilepsy

41 n two types of electrodes, carbon fiber disk microelectrodes and nanotip conical-shape carbon fiber m

42 mical, and nanomechanical properties of gold microelectrodes and of gold electrodes patterned onto po

43 Rats were implanted with cortical recording microelectrodes and spinal cord stimulating electrodes,

44 ng SMI of NCs/NPs as electrically conductive microelectrodes and surface-mediated assembly (SMA) of t

45 Using ion-selective microelectrodes and Xenopus oocytes, here we studied Cl(

46 ance at 1 kHz, whereas PEDOT:PSS coated flat microelectrodes appears delamination.

47 Orthogonal band microelectrodes are arranged to form at their intersecti

48 advantages of using carbon fiber or platinum microelectrodes are because they are promising materials

49 Intracortical microelectrodes are being developed to both record and s

50 The individual Au microelectrodes are further selectively functionalized w

51 Flexible wrinkled microelectrodes are further verified by in-vivo ECoG rec

52 Microelectrodes are typically used for neurotransmitter

53 microelectrodes, especially CNTs grown on Nb microelectrodes, are useful for monitoring neurotransmit

54 ith a thin polystyrene coating to define the microelectrode area was used as the working electrode; b

55 ip consists of a gold annular interdigitated microelectrode array (3x3 format with a sensing area of

56 nnel, high-density, intraneural carbon fiber microelectrode array (CFMA) with ultra-small electrodes

57 a low cost silicon based 16-site implantable microelectrode array (MEA) chip fabricated by standard l

58 We apply microelectrode array (MEA) measurements to assess networ

59 phic microfabrication of a movable thin film microelectrode array (MEA) probe consisting of 16 platin

60 Microelectrode array (MEA) technology in combination wit

61 d physiology, while cardiomyocyte-integrated microelectrode array (MEA) technology is set to be stand

62 using [Formula: see text] imaging, ESA using microelectrode array (MEA) technology, and dendritic com

63 ing ion conductance microscopy (SICM) with a microelectrode array (MEA) to image the three-dimensiona

64 phene oxide (rGO) has been fabricated into a microelectrode array (MEA) using a modified nanoimprint

65 test this hypothesis, a glutamate selective microelectrode array (MEA) was used to monitor dentate (

66 Cardiomyocytes (CM) placed on microelectrode array (MEA) were simultaneously probed wi

67 ere monitored with an integrated custom-made microelectrode array (MEA).

68 context, we developed a novel 384-multiwell microelectrode array (MMEA) based measurement system for

69 used a conducting polymer-based conformable microelectrode array (NeuroGrid) to record local field p

70 levates network activity, as demonstrated by microelectrode array analysis.

71 Here, we demonstrate a flexible cortical microelectrode array based on porous graphene, which is

72 Enzyme-based microelectrode array biosensors present the potential fo

73 The measurements were performed using a microelectrode array featuring 64 individually addressab

74 tion of an individually addressable 3 x 3 Au microelectrode array for rapid, multiplex detection of c

75 After development of an optimum microelectrode array for reliable and sensitive long-ter

76 ion of the proteolysis of cathepsin B on the microelectrode array functionalized with three different

77 lysis probes implanted at opposite ends of a microelectrode array in barrel cortex of anesthetized ra

78 ulatta) were implanted with an intracortical microelectrode array in the leg area of the motor cortex

79 the free-standing insoluble all-keratin made microelectrode array ionic sensor pave the way for the e

80 The band microelectrode array is covered with a layer of permeabl

81 The placement of a peptide onto a microelectrode array is frequently complicated by the pr

82 we analyze such oscillations in high-density microelectrode array recordings in human and monkey duri

83 method to track neuronal firing, we analyzed microelectrode array recordings of spontaneously occurri

84 The microelectrode array sites showed a very smooth surface

85 Using a 32-microelectrode array spanning the depth of cortex, elect

86 neurons are recorded by chronically coupling microelectrode array to rat's gustatory cortex with brai

87 with an unfolded hippocampus and penetrating microelectrode array to record and analyze neural activi

88 e used a chronically implanted intracortical microelectrode array to record multiunit activity from t

89 recorded from a ventricular ganglion using a microelectrode array, and cardiac electrophysiological m

90 form of a ceramic-substrate enabled platinum microelectrode array, that continuously, in real time, m

91 folded rodent hippocampus with a penetrating microelectrode array, we have shown that fast and slow w

92 ded neural activity at 32 locations with the microelectrode array.

93 Three-dimensional microelectrode arrays (3D MEAs) have emerged as promisin

94 al prefrontal cortex of macaques using eight microelectrode arrays (768 electrodes), from which we we

95 Interdigitated gold microelectrode arrays (IDAs) were first modified with a

96 ronal network activity (ivNNA) recorded with microelectrode arrays (MEA).

97 erived from hESCs and hiPSCs were made using Microelectrode Arrays (MEA).

98 ) and viability observations, or onto planar microelectrode arrays (MEAs) for electrophysiological me

99 Culturing primary neuron explants on planar microelectrode arrays (MEAs) has emerged as one of the m

100 Recent advances using high-density microelectrode arrays (MEAs) have allowed clinicians to

101 Cultured neuronal networks monitored with microelectrode arrays (MEAs) have been used widely to ev

102 cordings from the M72 OSNs by implanting the microelectrode arrays (MEAs) into the behaving mouse's O

103 used spontaneously active networks grown on microelectrode arrays (MEAs) to allow long-term multisit

104 o reduce experimental complexity, we coupled microelectrode arrays (MEAs) to bi-level microchannel de

105 present work, we used ceramic-based platinum microelectrode arrays (MEAs) to perform high-frequency a

106 ndividual gold electrode sites along silicon microelectrode arrays (MEAs) to produce a multisite DA s

107 Ceramic-based multisite Pt microelectrode arrays (MEAs) were characterized for thei

108 ability in 5xFAD mice, measured in vivo with microelectrode arrays and ex vivo brain slices, using wh

109 f the macaque cortical grasping circuit with microelectrode arrays and found cooperative but anatomic

110 rks in vitro, employing substrate-integrated microelectrode arrays and long-term cultured neuronal ne

111 eparately in complementary experiments using microelectrode arrays described previously (Shew et al.,

112 was based on a novel dual-biosensor based on microelectrode arrays designed to simultaneously monitor

113 Individually accessible microelectrode arrays enabled by semiconductor fabricati

114 Previous works describing microelectrode arrays have exploited the interelectrode

115 ctivity was measured with 64-channel silicon microelectrode arrays in cortical layers 5/6 of the prim

116 Using high-density microelectrode arrays in nonhuman primates, we recorded

117 y we used chronically implanted high density microelectrode arrays in primary motor cortex (M1) to re

118 He received two intracortical microelectrode arrays in the hand area of his motor cort

119 we measured population neural activity with microelectrode arrays in turtle visual cortex while visu

120 some stimulus conditions, separate ECoG and microelectrode arrays in two additional male macaques we

121 tivity in M1 was recorded using high-density microelectrode arrays in two parkinsonian nonhuman prima

122 ethiol monolayers at the surface of platinum microelectrode arrays on the stochastic amperometric det

123 ion was performed in rats and showed that GC microelectrode arrays recorded somatosensory evoked pote

124 Here, we tested this hypothesis by using microelectrode arrays to examine spike count correlation

125 Conventional microelectrode arrays used for these types of applicatio

126 nd free-standing graphene-fiber- (GF-) based microelectrode arrays with a thin platinum coating, acti

127 al field potentials (LFPs), using 98-channel microelectrode arrays, in functionally distinct primary

128 cardiomyocyte syncytium to planar multiwell microelectrode arrays, resulting in a stable, label-free

129 Using mapping with microelectrode arrays, we demonstrate spatially scattere

130 Using microelectrode arrays, we examined binocular interaction

131 wo human tetraplegic subjects implanted with microelectrode arrays, who performed a recognition memor

132 ngs with population statistics obtained with microelectrode arrays.

133 neously recorded using chronically implanted microelectrode arrays.

134 nd posterior IT (PIT) from six monkeys using microelectrode arrays.

135 through electrochemical deposition on neural microelectrodes arrays (MEA).

136 g an alternating current (ac) polarized disk microelectrode as a probe.

137 ) in the extracellular medium using platinum microelectrodes, as a function of cellular exposure time

138 lled distance, which was achieved by a three-microelectrode-assisted tilt correction.

139 arbors in cortical cultures with hundreds of microelectrodes at microsecond temporal resolution.

140 brane potential measured using intracellular microelectrodes averaged approximately -70 mV.

141 le, single-masked gold interdigitated triple-microelectrodes biosensor is presented by taking the adv

142 Ecoflex) is proposed for the application of microelectrode biosensors.

143 ene expression profiles using nanostructured microelectrode biosensors.

144 hloride), carbon-based calcium ion-selective microelectrode (Ca(2+)-ISME), 25 mum in diameter, capabl

145 Moreover, we demonstrate that the GC microelectrodes can withstand at least 5 million pulses

146 z nanopipette positioned near a carbon-fiber microelectrode (CFE).

147 bon nanotube (PEDOT/CNT)-coated carbon fiber microelectrodes (CFEs) are capable of directly measuring

148 Fast scan cyclic voltammetry at carbon fiber microelectrodes (CFEs) is an effective method to monitor

149 CNTs can be grown on carbon fiber microelectrodes (CFMEs) but the intrinsic electrochemica

150 cyclic voltammetry (FSCV) using carbon-fiber microelectrodes (CFMs) is an emerging technique for meta

151 odification methods for carbon nanotube yarn microelectrodes (CNTYMEs): O2 plasma etching and antista

152 fering redox molecules and surpassed similar microelectrodes coated with a Nafion screening layer.

153 paired with a metal-thin film titanium oxide microelectrode connects a silicon neuron to a neuron of

154 routine acquisition of multimodal data with microelectrodes could be useful for biomedical applicati

155 ed NO in the living brain using carbon fiber microelectrodes covered with nickel porphyrin and this f

156 We report microelectrode data from the globus pallidus interna (GP

157 Single pass microelectrode data were obtained to guide electrode pos

158 ess than 7.5% impedance change, while the Pt microelectrodes delaminated after 1 million pulses.

159 The PEDOT:CNF modified microelectrodes demonstrated the low specific impedance

160 des, train durations, pulse frequencies, and microelectrode depths.

161 The HNG microelectrode developed in the present study may provid

162 nsing principles: nanopores and amperometric microelectrode devices.

163 uch as stimulators, amplifiers and recording microelectrodes do not operate reliably at these high ra

164 awake adult male zebra finches with multiple microelectrodes during repeated playback of a conspecifi

165 er transfers the collected signals along the microelectrode efficiently.

166 an cyclic voltammetry (FSCV) at carbon-fiber microelectrodes enables the localized in vivo monitoring

167 ized and partially insulated to be used as a microelectrode enabling electrochemical substrate enhanc

168 This study demonstrates that CNT-grown metal microelectrodes, especially CNTs grown on Nb microelectr

169 lic voltammetry, CNT-coated niobium (CNT-Nb) microelectrodes exhibit higher sensitivity and lower Del

170 Carbon nanotube (CNT) based microelectrodes exhibit rapid and selective detection of

171 Wrinkled gold microelectrodes exhibit superior electrochemical propert

172 The hierarchical nanoporous gold (HNG) microelectrode exhibited excellent performance for the d

173 ts with chronically indwelling intracortical microelectrodes exhibited up to an incredible 527% incre

174 ted electrochemically reduced graphene oxide microelectrode for HT-2 mycotoxin immunoenzymatic biosen

175 r developing next-generation multifunctional microelectrodes for applications in neural therapies.

176 Aptamer-modified microelectrodes for Neuropeptide Y measurement by electr

177 we investigated CNTs grown on metal wires as microelectrodes for neurotransmitter detection.

178 nt a suite of glass pipettes with integrated microelectrodes for the simultaneous acquisition of mult

179 Voltage signals were recorded using microelectrodes from control scars but no signals were o

180 zoactive surface acoustic waves (SAWs) or by microelectrode-generated electric fields, both at freque

181 p between two arrays of oppositely polarized microelectrodes, generating a magnetohydrodynamic flow.

182 active species, which was detected at a soft microelectrode, gently brushed in contact mode over the

183 Conductive polymer, PEDOT:PSS, coated microelectrodes have an advantage that they can be made

184 fabrication strategies and geometries of CNT microelectrodes have been characterized, relatively litt

185 The GC microelectrodes have more than 70% wider electrochemical

186 HD-CNTf rods microelectrodes have open-ended CNTs exposed at the inte

187 Intracortical microelectrodes have shown great success in enabling loc

188 In this context, microelectrodes have the analytical advantages of reduce

189 FSCV detection of histamine at carbon-fiber microelectrodes, histamine oxidation was adsorption-cont

190 effect transistor with inter-digitated gold microelectrodes (IDuE) for the detection of the malaria

191 ce aptasensor was composed of interdigitated microelectrodes (IMEs), carboxylated polypyrrole nanotub

192 imed to quantify any motor deficit caused by microelectrode implantation in the motor cortex of healt

193 ng of potential unintentional harm caused by microelectrode implantation.

194 In vivo studies show that microelectrodes implanted in the rat cerebral cortex can

195 ated ICC and also that of cells impaled with microelectrodes in intact muscle strips.

196 Using microelectrodes in seizure-generating deep mesial region

197 The nine individual microelectrodes in the array show highly consistent cycl

198 s was developed which employs a carbon-fiber microelectrode incorporated into a multibarreled iontoph

199 y recording extracellularly with penetrating microelectrodes inserted into the DRG.

200 t protein biomarker of sepsis, using a novel microelectrode integrated onto a needle shaped substrate

201 This was accomplished by advancing a microelectrode into various locations of the lumbar enla

202 he limit of detection for dopamine at CNT-Nb microelectrodes is 11 +/- 1 nM, which is approximately 2

203 approach in conjunction with nanostructured microelectrodes is an advantageous alternative to conven

204 of local field potential (LFP) obtained from microelectrodes is debated, with estimates ranging from

205 e text], using liquid membrane ion-selective microelectrodes (ISM), however, has been limited by the

206 ous material architecture, an interdigitated microelectrode layout and a supercapacitor-like performa

207 We demonstrated that eSHHA on nanostructured microelectrodes leverages three effects: (1) steric hind

208 that TPEs behave as a network of interacting microelectrodes made by electrochemically active islands

209 hat could increase the risk of bleeding from microelectrode mapping.

210 ical microscopy-(SECM) like approach of a Pt microelectrode (ME), which was leveled with the WE towar

211 tration is determined by peak current on the microelectrodes measured by a differential pulse voltamm

212 ain-to-silicon link is established through a microelectrode-memristor pair.

213 d manipulate fluid in a contactless way in a microelectrode-microfluidic system is demonstrated by co

214 ments were also carried out with a gold disc microelectrode modified with a film of iridium oxide and

215 ovel electrochemical biosensor based on gold microelectrodes modified with a new structure of magneti

216 Microelectrodes modified with carbon nanotubes (CNTs) ar

217 Here, we report the use of a nanostructured microelectrode (NME) platform for eSHHA that improves th

218 For the modified microelectrodes, no significant change is observed in ch

219 by interfacing graphene with interdigitated microelectrodes of capacitors that were biofunctionalize

220 igher CTC (charge transfer capacity) than Pt microelectrodes of similar geometry.

221 ted by screen-printing carbon interdigitated microelectrodes on a flexible plastic substrate and util

222 The biosensor, consists of two gold microelectrodes on a glass substrate embedded in a PDMS

223 -HT overflow has been achieved to date using microelectrodes on a small segment of colonic tissue; ho

224 The 25 mum diameter H(+) ion-selective microelectrode or pH microprobe showed a Nernstian slope

225 or in combination with pH/voltage-sensitive microelectrodes or confocal fluorescence imaging of plas

226 Thus, these Pt MEAs provide an excellent microelectrode platform for multisite O2 recording in vi

227 a novel platform featuring 3D free-standing microelectrodes presenting passive upstream and downstre

228 cal irradiation of the analyzed sample and a microelectrode probe for the localized electrochemical a

229 Microelectrode profiles of sulfide, oxygen, and pH indic

230 chieved through the use of a random array of microelectrodes (RAM) integrated into a purpose-built fl

231 review, we will concentrate on BMIs in which microelectrode recording arrays are implanted in the pos

232 Microelectrode recording of SHR hearts showed that VT wa

233 operties of human subthalamic neurons, using microelectrode recordings and microstimulation during aw

234 In particular, microelectrode recordings enable the delineation of neur

235 Furthermore, we performed simultaneous microelectrode recordings from 6 areas of macaque cortex

236 pon stimulus onset, similar to findings from microelectrode recordings in animal studies.

237 Here, continuous oxygen microelectrode recordings in the coral diffusive boundar

238 Furthermore, we show that microelectrode recordings may describe a smoother tonoto

239 tify time cells in humans using intracranial microelectrode recordings obtained from 27 human epileps

240 In vivo microelectrode recordings of basal activity, as well as

241 ivity was electrophysiologically measured by microelectrode recordings.

242 ere measured using vibrating probe and glass microelectrodes, respectively.

243 ies, conducted electrochemically at platinum microelectrodes, revealed almost 50% of the Ag-Phen had

244 A dual-function platinum disc microelectrode sensor was used for in-situ monitoring of

245 In order to compare the sensitivity of the microelectrode sensor, the presence of H2O2 was detected

246 By using the tip microelectrode simultaneously for local irradiation and

247 system with up to 256 independently movable microelectrodes spanning an entire cerebral hemisphere.

248 was fabricated on the screen-printed carbon-microelectrode (SPE).

249 Across any given microelectrode, spike amplitudes ranged from 70 to 300mu

250 directly grown layer-by-layer on macro- and microelectrode substrates.

251 cotoxin based on carbodiimide linking of the microelectrode surface and HT-2 toxin antigen binding fr

252 silane modification) that are trapped on the microelectrode surface using programmable dielectrophore

253 compatible chitosan matrix was cast onto the microelectrode surface.

254 provided by aptamer functionalization of the microelectrode surface.

255 nsure Ppy-COOH/MNPs electrodeposition on the microelectrode surfaces.

256 rticles on the tip of a cathode in a coaxial microelectrode system, followed by ablation, atomization

257 left ventricular subendocardial slabs using microelectrode techniques.

258 This aptamer is immobilized on a gold microelectrode that is connected to the gate of a reusab

259 paper leads to the ion diffusion blockage on microelectrodes, therefore cell concentration is determi

260 t were promising for the characterization of microelectrode tips, their performance with nanoelectrod

261 (mPD) was electrodeposited on a carbon-fiber microelectrode to create a size-exclusion membrane, rend

262 mical experiment, this equates to the use of microelectrodes to lower the electrochemical cell consta

263 ability was investigated on PEDOT:CNF coated microelectrodes to show that the composite material does

264 e, we evaluated approach curves of nano- and microelectrodes to soft surfaces using SECM for a rapid

265 Gold microelectrode (uE) modified with Zinc based Metal Organ

266 ically amplified collisions with a Hg-coated microelectrode used as the tip in the scanning electroch

267 isol antibody (anti-CAB) on top of gold (Au) microelectrodes using 3,3'-dithiodipropionic acid di(N-h

268 of single Ag nanoparticles is observed at Au microelectrodes using stochastic single-nanoparticle col

269 ical system (Bio-MEMS) containing eight gold microelectrodes (uWEs), an integrated silver and platinu

270 unctional studies using a Xenopus oocyte two-microelectrode voltage clamp system revealed mutations w

271 el currents were characterized using the two-microelectrode voltage clamp technique.

272 xpressed in Xenopus laevis oocytes using two-microelectrode voltage clamp technique.

273 nd K(+) currents were measured using the two-microelectrode voltage-clamp technique.

274 The optimized HNG microelectrode was further utilized to monitor the relea

275 A new design of microelectrode was introduced to generate electrochemica

276 A microelectrode was placed in a region of the muscle cont

277 cally active surface area (ECSA) of the gold microelectrode was significantly increased by 22.9 times

278 he adsorption of NPY to the aptamer-modified microelectrodes was also demonstrated by EIS.

279 combining optogenetics with voltage-sensing microelectrodes, we demonstrate that plant plasma membra

280 Arrays of HD-CNTf rods microelectrodes were applied to detect neurotransmitters

281 The printed graphene oxide microelectrodes were electrochemically reduced and chara

282 In this study, arrays of eight (r = 25 um) microelectrodes were fabricated onto needle shaped silic

283 irst formulated and single-drop line working microelectrodes were inkjet-printed onto poly(ethylene 2

284 A 100 mum capillary and a pair of microelectrodes were inserted to the mouse brain to test

285 Carbon-based microelectrodes were modified with a [NiFe]-hydrogenase

286 The microelectrodes were redesigned with compact size, fabri

287 The developed microelectrodes were then used as an immunoenzymatic bio

288 used to label flattened-cut LJBSF sections, microelectrodes were used to map the lower jaw skin surf

289 CNT-Nb microelectrodes were used to monitor stimulated dopamine

290 Using eight gold working microelectrodes (WEs) the design will increase the sensi

291 tability and performance of the carbon-fiber microelectrode when studying the molecular mechanisms un

292 ycling forces are also conducted on modified microelectrodes, which demonstrates little influence on

293 Here we report on a novel gold microelectrode with a unique three-dimensional (3D) hier

294 crobiosensor consisted of a 30-microm carbon microelectrode with an open tip as a working electrode,

295 sorbed species with low surface coverages on microelectrodes with a geometric area of 25 x 25 mum(2).

296 i detection by modifying low cost commercial microelectrodes with an E. coli specific antibody.

297 imulation systems have relied on sharp metal microelectrodes with poor electrochemical properties tha

298 mbled in controlled patterns and directly on microelectrodes with UV-click-chemistry.

299 reaction by adsorption at the surface of the microelectrodes, with the specificity provided by aptame

300 EIS measurements taken across two microelectrodes within the fracture gap were able to tra