ライフサイエンスコーパス: carbon fiber

1 ning functional groups at the surface of the carbon fiber.

2 ound used in resins, polymers, acrylics, and carbon fiber.

3 r unloaded and loaded conditions using micro-carbon fibers.

4 peaks were detected for adenosine with T-650 carbon fibers.

5 al for the insulation of metal microwires or carbon fibers.

6 in the process used in the manufacturing of carbon fibers.

7 can improve the electrochemical response at carbon fibers.

8 site-specific nitrogen doping in microporous carbon fibers.

9 ely on the surface of commercial microporous carbon fibers.

10 ing precursor material for the production of carbon fibers.

11 ameters and cores were fabricated, including carbon fiber (7 and 11 mum), gold (10 and 25 mum), plati

12 ormed in the brain of anesthetized rats with carbon fiber amperometric sensors coated with a cross-li

13 expressing this mutant were characterized by carbon fiber amperometry and cell-attached patch capacit

14 K201Q, or K201E mutants were investigated by carbon fiber amperometry and cell-attached patch capacit

15 Carbon fiber amperometry is a popular method for measuri

16 Carbon fiber amperometry revealed that release of dopami

17 To address this question, we used carbon fiber amperometry to measure catecholamine secret

18 such as vibrating ion-selective electrodes, carbon fiber amperometry, and magnetic resonance imaging

19 Using carbon fiber amperometry, we found that exocytosis is im

20 rat cultured ventral midbrain neurons using carbon fiber amperometry.

21 Carbon-fiber amperometry detects oxidizable molecules re

22 Carbon-fiber amperometry has been extensively used to mo

23 icles in NGF-differentiated PC12 cells using carbon-fiber amperometry, and relative diameters of indi

24 rojunction amplifies the interaction between carbon fiber and CO2 molecule for unusually high CO2 upt

25 erform equivalently filled randomly oriented carbon fiber and polymer composites.

26 Carbon fibers and lobster exoskeleton as examples of bio

27 nergy-loss spectroscopy (EELS) of individual carbon fibers and MWNTs as a characterization tool to co

28 were prepared by electrochemical etching of carbon fibers and subsequent coating with electrodeposit

29 n the presence of solids (aramid fibers, and carbon fibers, and glass fibers).

30 D-loops, a new type of structural defect in carbon fibers, are presented, which have highly detrimen

31 e developed a novel implantable enzyme-based carbon fiber biosensor for in vivo monitoring of dopamin

32 ion mass spectrometry (CFI-MS), which uses a carbon fiber bundle as the ion source, is useful for the

33 Voltage needs to be applied on the carbon fiber bundle to initiate corona discharge for ion

34 onses as a direct result of the alignment of carbon fiber bundles in the microscale which we predict

35 ved from polymers, gel spun fibers, modified carbon fibers, carbon-nanotube fibers, ceramic fibers, a

36 In this work, a carbon fiber (CF) microelectrode is used to monitor effl

37 fiber (CNTF) microelectrode to a traditional carbon fiber (CF) microelectrode.

38 bunched TiO(2) nanorod (NR) arrays grown on carbon fibers (CFs) from titanium by a "dissolve and gro

39 Carbon cloth (CC) woven by carbon fibers (CFs) is typically used as electrode or cu

40 The use of adsorption on activated carbon fiber cloth (ACFC) followed by electrothermal swi

41 ic compounds from gas streams with activated carbon fiber cloth (ACFC) reduces emissions to the atmos

42 anular activated carbon (GAC), and activated carbon fiber cloth (ACFC) systems to treat gaseous emiss

43 g reinforcement component using magnesium or carbon fiber composite for 83 different vehicle models.

44 Furthermore, our AM carbon fiber composite systems exhibit highly orthotropi

45 In this work, honeycomb monolithic carbon fiber composites were developed and employed to c

46 This study shows that marrying carbon fiber composites with natural cork in a sandwich

47 means of printing high performance thermoset carbon fiber composites, which allow the fiber component

48 esigned, facilitating the visualization of a carbon fiber (diameter 7.0 mum) electrochemical interfac

49 be monitored with amperometry by placing the carbon fiber directly on the larger synaptic terminal.

50 lyeugenol or o-phenylenediamine on 30-microm carbon fiber disk electrodes.

51 Here, characterization of a 10 mum Hg film carbon fiber disk microelectrode to accumulate f-element

52 a dimethylformamide (DMF) suspension onto a carbon-fiber disk microelectrode modified with a thin ir

53 prised only of two bioelectrocatalyst-coated carbon fibers, each of 7 micro m diameter and 2 cm lengt

54 ation of the droplets at an optically opaque carbon fiber electrode (diameter approximately 7.5 mum)

55 mance was facilitated by the design of a new carbon fiber electrode (ProCFE) described within.

56 It was attached to the tip of a carbon fiber electrode by cross-linking with 5% glutaral

57 y time, and half-width as compared to a bare carbon fiber electrode equivalent.

58 age the diffusion layer of a 10 mum diameter carbon fiber electrode over the course of a cyclic volta

59 roximately 45 mV, much sharper than those of carbon fiber electrode recordings.

60 the added sine wave on the voltammetry at a carbon fiber electrode was investigated and found to hav

61 nse to glucose at a glucose oxidase modified carbon fiber electrode.

62 re detected at a 10-microm-diameter tip of a carbon fiber electrode.

63 roA, with noise levels at or below 1 pA at a carbon fiber electrode.

64 mplification of proton reduction on an inert carbon fiber electrode.

65 ed with fast-scan cyclic voltammetry using a carbon-fiber electrode placed next to a single cell.

66 aves that arise from species confined to the carbon-fiber electrode surface.

67 h cases, the modification did not affect the carbon-fiber electrode's responsiveness to changes in pH

68 to measure reward-evoked dopamine release at carbon fiber electrodes chronically implanted in the nuc

69 e-coated electrode were compared to those at carbon fiber electrodes coated with Nafion, a perfluorin

70 mperometric detection of 5-HT performed with carbon fiber electrodes implanted in the vicinity of tai

71 We demonstrate that carbon fiber electrodes with reduced tip diameters can b

72 istent with those obtained with conventional carbon fiber electrodes.

73 release events was similar for platinum and carbon fiber electrodes.

74 to modify the surface of 30 microns diameter carbon fiber electrodes.

75 obacter spp. and Methanobacterium spp. using carbon-fiber electrodes as the terminal electron sink.

76 jection of charged and neutral species using carbon-fiber electrodes attached to iontophoretic barrel

77 overpotential and a high faradaic current at carbon-fiber electrodes for NADH.

78 However, during cyclic voltammetry with carbon-fiber electrodes the current varies with changes

79 signal-to-noise ratio comparable to that of carbon-fiber electrodes.

80 nd electrode design consists of two adjacent carbon fibers embedded in an epoxy matrix and is analogo

81 The use of the carbon fiber emitter for interfacing monolithic capillar

82 Using a solution of angiotensin I, the carbon fiber emitter in 75-microm-i.d. fused-silica tubi

83 uses for this biopolymer, including low-cost carbon fibers, engineered plastics and thermoplastic ela

84 The resulting carbon fiber exhibits microstructural and topological pr

85 A flexible nanoporous carbon-fiber film for wearable electronics is prepared b

86 rechargeable zinc-air batteries based on the carbon-fiber film show high round-trip efficiency and me

87 ich allow the fiber component of a resin and carbon fiber fluid to be aligned in three dimensions via

88 f the interior microstructure of the treated carbon fiber, for both electroactive and electroinactive

89 zes, different electrode materials including carbon fibers, glassy carbon rods, poly(tetrafluoroethyl

90 spray ionization emitter employing a pointed carbon fiber has been developed for interfacing nanoliqu

91 he important new result is that Au wires and carbon fibers having diameters ranging from micrometers

92 Carbon fibers having unique morphologies, from hollow ci

93 tibarrel glass capillary containing a single carbon fiber in each barrel into a sharp tip, followed b

94 recovery of 100% of the imine components and carbon fibers in their original form.

95 Carbon fiber ionization mass spectrometry (CFI-MS), whic

96 Furthermore direct electric contact on the carbon fiber is not required.

97 The carbon fiber is surface-mounted onto an inert surface to

98 por, liquid, and solid phases using a single carbon fiber (length : approximately 1 cm; diameter: app

99 ut the intrinsic electrochemical activity of carbon fibers makes evaluating the effect of CNT enhance

100 siloxane (PDMS) glue, which is spread onto a carbon fiber mesh.

101 First a gold surface is obtained on a carbon fiber microdisk electrode by partially etching aw

102 In this work, a carbon fiber microdisk electrode was used to monitor dir

103 Nanostructured carbon fiber microdisk electrodes were prepared by a com

104 electrochemical cell consisted of a beveled carbon fiber microdisk working electrode and a reference

105 Carbon-fiber microelectrochemical methods were utilized

106 ectrochemical methods, principally with disk carbon fiber microelectrode amperometry.

107 lations obtained from PC12 cells with a disk carbon fiber microelectrode and with a pyrolyzed carbon

108 de and 2.7 cm s(-1) for the Cc(+/0) one at a carbon fiber microelectrode in acetonitrile (0.1 M Bu4NP

109 icin (DOX) concentration is monitored with a carbon fiber microelectrode in vitro at close proximity

110 into the fluid inflow of the organism and a carbon fiber microelectrode placed in the fluid outflow'

111 nel of the pulled glass capillary contains a carbon fiber microelectrode sealed in epoxy while the ot

112 micrometer-wide stripes on an enzyme-covered carbon fiber microelectrode surface to create regions of

113 dehydrogenase, were then covalently bound to carbon fiber microelectrode surfaces in order to verify

114 We employed carbon fiber microelectrode voltammetry (chronoamperomet

115 etal oxides, deposited onto the surface of a carbon fiber microelectrode with a diameter of approxima

116 easy, precise, and permanent alignment of a carbon fiber microelectrode with a separation capillary

117 ablation of the surface of a protein-covered carbon fiber microelectrode with an interference pattern

118 contents with a 3-microm radius, disk-shaped carbon fiber microelectrode within 60 s.

119 ydrogen peroxide fluctuations at an uncoated carbon fiber microelectrode, demonstrating unprecedented

120 ming a gold-nanoparticle (AuNP) network on a carbon fiber microelectrode.

121 ol of the electrochemically active area of a carbon fiber microelectrode.

122 xes that are detected electrochemically at a carbon fiber microelectrode.

123 d amperometrically at a cylindrical 9-micron carbon fiber microelectrode.

124 cking microfluidic analysis, and single cell carbon-fiber microelectrode amperometry (CFMA).

125 In this work, carbon-fiber microelectrode amperometry is used to chara

126 asurement of individual granule release with carbon-fiber microelectrode amperometry.

127 n efficiency with varied spacing between the carbon-fiber microelectrode and the platelet, it is clea

128 Mechanistic studies using carbon-fiber microelectrode fast-scan cyclic voltammetry

129 time using fast-scan cyclic voltammetry at a carbon-fiber microelectrode in vitro in striatal section

130 iontophoresis was developed which employs a carbon-fiber microelectrode incorporated into a multibar

131 ylenediamine (mPD) was electrodeposited on a carbon-fiber microelectrode to create a size-exclusion m

132 oncentrations of dopamine, and a cylindrical carbon-fiber microelectrode was placed in the protocereb

133 mproves the stability and performance of the carbon-fiber microelectrode when studying the molecular

134 fast-scan cyclic voltammetry at an implanted carbon-fiber microelectrode.

135 ix jacchus) using fast-scan voltammetry at a carbon-fiber microelectrode.

136 electrode array and dopamine dynamics from a carbon-fiber microelectrode.

137 Carbon-fiber-microelectrode arrays (MEAs) have been util

138 To prepare glutamate microsensors, carbon fiber microelectrodes (10 microns in diameter and

139 Fast scan cyclic voltammetry at carbon fiber microelectrodes (CFEs) is an effective meth

140 CNTs can be grown on carbon fiber microelectrodes (CFMEs) but the intrinsic e

141 cal selectivity and fouling of commonly used carbon fiber microelectrodes (CFMs).

142 key advantageous properties inherent to bare carbon fiber microelectrodes (i.e., rigidity, flexibilit

143 time were comparable with those measured by carbon fiber microelectrodes and allowed to identify thr

144 ole have been electro-chemically coated onto carbon fiber microelectrodes and used for dopamine measu

145 Carbon fiber microelectrodes are state-of-the-art tools

146 Carbon fiber microelectrodes have been used to monitor a

147 We used carbon fiber microelectrodes in a brainstem slice to ass

148 highlights the current status of the use of carbon fiber microelectrodes in neurochemical measuremen

149 ch to study it directly by amperometry using carbon fiber microelectrodes in organotypic rat brainste

150 Whereas fast-scan cyclic voltammetry with carbon fiber microelectrodes is used frequently to monit

151 ifferential pulse voltammetry with implanted carbon fiber microelectrodes modified with carbon nanotu

152 Carbon fiber microelectrodes provide the ideal platform

153 Amperometry at the carbon fiber microelectrodes revealed unitary events in

154 xperiments recorded the dopamine signal from carbon fiber microelectrodes stereotaxically passed thro

155 this study demonstrates the applicability of carbon fiber microelectrodes to the measurement of quant

156 al properties comparable to PAN-type, T-650, carbon fiber microelectrodes using background-subtracted

157 Fast-scan cyclic voltammetry at carbon fiber microelectrodes was used to monitor the con

158 Carbon fiber microelectrodes were used to measure indivi

159 Using amperometric detection at carbon fiber microelectrodes, time-resolved exocytosis o

160 Using carbon fiber microelectrodes, we found the concentration

161 Amperometric detection using carbon fiber microelectrodes, which provides high tempor

162 photoresist insulates the 10-microm-diameter carbon fiber microelectrodes.

163 easured with fast scan cyclic voltammetry at carbon fiber microelectrodes.

164 by deposition of hydrous iridium oxide onto carbon fiber microelectrodes.

165 ry (FSCV) method for Pb detection on Hg-free carbon fiber microelectrodes.

166 chitosan electrodeposition on the surface of carbon fiber microelectrodes.

167 ed fast-scan cyclic voltammetry (FSCV) using carbon-fiber microelectrodes (CFME) to detect GnRH relea

168 Dopamine oxidation at carbon-fiber microelectrodes (CFMEs) is dependent on dop

169 ive for serotonin detection than traditional carbon-fiber microelectrodes (CFMEs).

170 Fast-scan cyclic voltammetry (FSCV) using carbon-fiber microelectrodes (CFMs) is an emerging techn

171 etected with fast-scan cyclic voltammetry at carbon-fiber microelectrodes (peak amplitude, 210 +/- 10

172 uinea-pig striatal slices was monitored with carbon-fiber microelectrodes and fast-scan cyclic voltam

173 pig striatum and monitored in real time with carbon-fiber microelectrodes and fast-scan cyclic voltam

174 elease was assessed in striatal slices using carbon-fiber microelectrodes and fast-scan cyclic voltam

175 Evoked [DA](o) was monitored with carbon-fiber microelectrodes and fast-scan cyclic voltam

176 Carbon-fiber microelectrodes are frequently used as chem

177 The coating is deposited on carbon-fiber microelectrodes by applying a triangle wave

178 Carbon-fiber microelectrodes coupled with electrochemica

179 tion, fast-scan cyclic voltammetry (FSCV) at carbon-fiber microelectrodes enables the localized in vi

180 ne adrenal medullary cells was measured with carbon-fiber microelectrodes firmly touching the cell su

181 ast-scan deposition-stripping voltammetry at carbon-fiber microelectrodes for in situ measurements of

182 es have been investigated as alternatives to carbon-fiber microelectrodes for the detection of neurot

183 ed fast-scan cyclic voltammetry coupled with carbon-fiber microelectrodes has proven to be sensitive

184 In particular, carbon-fiber microelectrodes have been employed for the

185 nce of the system, data were collected using carbon-fiber microelectrodes in a flow injection analysi

186 ine (DA) release monitored in real time with carbon-fiber microelectrodes in guinea pig striatal slic

187 ired detection of evoked dopamine release at carbon-fiber microelectrodes in mouse striatal slices wi

188 elease using fast-scan cyclic voltammetry at carbon-fiber microelectrodes in striatal slices from mic

189 imultaneous detection of dopamine release at carbon-fiber microelectrodes in striatal slices.

190 0 msec using fast-scan cyclic voltammetry at carbon-fiber microelectrodes in the nucleus accumbens of

191 bis(dimethylphosphino)ethane, was studied at carbon-fiber microelectrodes of approximately 5 microm i

192 unit area for 1 microM dopamine than normal carbon-fiber microelectrodes or electrochemically etched

193 Amperometry with carbon-fiber microelectrodes provides a unique way to me

194 In this work we use two carbon-fiber microelectrodes to simultaneously measure d

195 s; fast-scan cyclic voltammetry (FSCV) using carbon-fiber microelectrodes was chosen on the basis of

196 Previously, fast-scan cyclic voltammetry at carbon-fiber microelectrodes was used for the measuremen

197 Fast-scan cyclic voltammetry (FSCV) at carbon-fiber microelectrodes was used in microfluidic ch

198 st-scan cyclic voltammetry at Nafion-coated, carbon-fiber microelectrodes was used to monitor extrace

199 In this work, we demonstrated that carbon-fiber microelectrodes when backfilled with an ele

200 iological adenosine concentration changes at carbon-fiber microelectrodes with subsecond temporal res

201 osite polymer has been electropolymerized on carbon-fiber microelectrodes with the goal of creating a

202 asured using fast-scan cyclic voltammetry at carbon-fiber microelectrodes, was diminished in transgen

203 , has been electrodeposited onto cylindrical carbon-fiber microelectrodes.

204 c shell with fast-scan cyclic voltammetry at carbon-fiber microelectrodes.

205 amine-o-quinone adsorption and desorption at carbon-fiber microelectrodes.

206 ltammetry of [Fe(CN)6]3-/[Fe(CN)6]4- at bare carbon-fiber microelectrodes.

207 for fabricating cylindrical, Nafion-coated, carbon-fiber microelectrodes.

208 -scan cyclic voltammetry (FSCV) coupled with carbon-fiber microelectrodes.

209 at BNST with fast-scan cyclic voltammetry at carbon-fiber microelectrodes.

210 methods of fabrication of small, cylindrical carbon-fiber microelectrodes: flame-etching and electroc

211 een ssDNA aptamer-functionalized AgNPs and a carbon fiber miroelectrode (CFME).

212 Here we present the fabrication of flexible carbon fibers modified with nitrated carbon nanoblisters

213 ower DeltaEp value compared to CNTs grown on carbon fibers or other metal wires.

214 rode array consisting of two 10 mum diameter carbon fibers over the course of a potential step experi

215 des composed of CoSe2 nanoparticles grown on carbon fiber paper.

216 ately lead to the design of truly tailorable carbon fiber/polymer hybrid materials having locally pro

217 n cyclic voltammetry implementing microsized carbon fiber probe implants to record fast millisecond c

218 information about a substrate using a single carbon fiber probe.

219 The pointed carbon fiber protruding from an orifice with a surroundi

220 i4.4 Ge NCs were conformally encapsulated in carbon fibers, providing great opportunities for studyin

221 xample of a class of additively manufactured carbon fiber reinforced composite (AMCFRC) materials whi

222 ant vehicle material) with wrought aluminum, carbon fiber reinforced plastic (CRFP), or magnesium wil

223 of oxygen distribution above an Al-Cu-CFRP (Carbon Fiber Reinforced Polymer) galvanic corrosion cell

224 Carbon-fiber reinforced composites are prepared using ca

225 a three-dimensional lattice of mass-produced carbon fiber-reinforced polymer composite parts with int

226 yl cellulose, carbon black, and vapor ground carbon fibers seems to be determinant in the excellent p

227 To evaluate the in vivo performance of the carbon-fiber sensor, carbon dioxide inhalation by an ane

228 th and target metals on the glassy-carbon or carbon-fiber substrate.

229 desirable to create in situ catalysts on the carbon fiber support to simplify the fabrication process

230 he novel microbiosensor consists of a simple carbon fiber surface modified with an electrodeposited c

231 The electrochemical kinetics of the same carbon fiber surface were examined through the electroge

232 The electrochemical kinetics of the carbon fiber surface were examined to see if electron-tr

233 a developing solution reveals electroactive carbon fiber surface.

234 Carbon fiber-synthetic foam core sandwich composites are

235 These FNGs are based on carbon fibers that are covered cylindrically by textured

236 eviously shown to occur at high surface area carbon fibers that were produced by fracturing the outer

237 oelectrode that was fabricated from a single carbon fiber (Thornel type T650 or P55).

238 Conical carbon fiber tips of submicrometer size were used to app

239 ical microscopy (SECM) using carbon ring and carbon fiber tips.

240 electrodes were constructed by flame etching carbon fibers to a fine point.

241 are prepared by the activation of commercial carbon fibers to have three-orders of magnitude increase

242 ticle (Pd-NP) collisions to the surface of a carbon fiber ultramicroelectrode (CFUME).

243 An inert carbon fiber ultramicroelectrode (UME) was held at a pot

244 ution using an array containing roughly 1000 carbon fiber ultramicroelectrodes.

245 uce to Pt(0) at the applied potential on the carbon fiber UME, cathodic blips were observed in the am

246 en-functionalized graphene on the surface of carbon fibers using Ar plasma treatment is successfully

247 The growth of long carbon fibers was investigated using hyperbaric-pressure

248 ngth, stiffness, and thermal conductivity of carbon fibers with the specific electrical conductivity

249 An integrated system consisting of a carbon fiber-ZnO hybrid nanowire (NW) multicolor photode