ライフサイエンスコーパス: magnetoencephalography

1 l activity with millisecond resolution using magnetoencephalography.

2 ined magnetic field amplitude, measured with magnetoencephalography.

3 aintenance of variably visible stimuli using magnetoencephalography.

4 od, using a brain recording technique called magnetoencephalography.

5 ssions by monitoring cortical activity using magnetoencephalography.

6 n neuronal oscillatory power, as measured by magnetoencephalography.

7 l magnetic stimulation (TMS) with subsequent magnetoencephalography.

8 ULFMRI include integration with systems for magnetoencephalography.

9 ng therapy-induced behavioural changes using magnetoencephalography.

10 , either of different or the same sex, using magnetoencephalography.

11 llations in the gamma band, as measured with magnetoencephalography.

12 hile their brain activity was recorded using magnetoencephalography.

13 gements about 400 pictures during continuous magnetoencephalography.

14 , recorded with high temporal resolution via magnetoencephalography.

15 esponses as measured in normal subjects with magnetoencephalography.

16 pants completed an attention protocol during magnetoencephalography.

17 retrieval of these episodes while undergoing magnetoencephalography.

18 hile recording their cortical activity using magnetoencephalography.

19 ed a time interval while being recorded with magnetoencephalography.

20 ion (spatial frequency) across saccades with magnetoencephalography.

21 ch while recording their brain activity with magnetoencephalography.

22 al power, which we tested with resting-state magnetoencephalography.

23 IFG regions was examined using event-related magnetoencephalography.

24 redictable, aversive shocks while undergoing magnetoencephalography.

25 In this experiment using human magnetoencephalography, 12 young healthy adults listened

26 free, macaque electrocorticography and human magnetoencephalography activity were correlated globally

27 recorded in healthy human participants with magnetoencephalography after intravenous infusion of psi

28 Magnetoencephalography allows non-invasive whole-brain r

29 Magnetoencephalography also shows promise in this regard

30 rrent study, we addressed this question with magnetoencephalography and a delayed match-to-sample tas

31 In this study, we used magnetoencephalography and a mismatch paradigm to invest

32 nal architecture of the auditory system with magnetoencephalography and a mismatch paradigm.

33 nd connectivity in the visual domain we used magnetoencephalography and a simple visual grating parad

34 We used magnetoencephalography and an antisaccade task to invest

35 In this preliminary study, we used magnetoencephalography and an integrative approach to ex

36 sounds in a multitalker auditory scene using magnetoencephalography and corticovocal coherence analys

37 We acquired simultaneously magnetoencephalography and direct recordings from the su

38 Here we tested this hypothesis using magnetoencephalography and electrocorticography in human

39 ultivariate decoding methods to single-trial magnetoencephalography and electroencephalography data.

40 Using magnetoencephalography and electroencephalography of a G

41 To investigate these questions, we used magnetoencephalography and examined the neural oscillato

42 ms of objects, faces versus houses, and used magnetoencephalography and functional magnetic resonance

43 New functional MRI-magnetoencephalography and functional MRI-EEG studies pr

44 Our present combined magnetoencephalography and genome-wide linkage study in

45 Patients (n = 28) underwent resting-state magnetoencephalography and neuropsychological assessment

46 Employing magnetoencephalography and psychoacoustics it is demonst

47 mulation, positron emission tomography, MRI, magnetoencephalography and quantitative EEG improve our

48 ping, capitalizing on the time resolution of magnetoencephalography and the unique clinical model off

49 Here, we used magnetoencephalography and TMS to investigate the effect

50 ing studies, including structural brain MRI, magnetoencephalography and transcranial magnetic stimula

51 heta coupling: a spatial memory task (during magnetoencephalography) and a memory integration task.

52 en, whole-brain measures of neural activity (magnetoencephalography) and connectivity (fMRI) to ident

53 Here, we compared temporal (magnetoencephalography) and spatial (functional MRI) vis

54 We use behavioral methods, magnetoencephalography, and functional MRI to investigat

55 cross detection and attention tasks in human magnetoencephalography, and in local field potentials fr

56 tate functional MRI, electroencephalography, magnetoencephalography, and optical imaging studies in p

57 We used functional MRI, magnetoencephalography, and phase synchrony analyses to

58 isual gamma peak frequency, as measured with magnetoencephalography, and resting GABA levels, as meas

59 was recorded using multi-channel whole-head magnetoencephalography, and the timecourse of lexically-

60 Brain activity was recorded with magnetoencephalography, and time-locked responses to the

61 Here, we used a source-level magnetoencephalography approach to investigate the hypot

62 ns and matched sighted control subjects with magnetoencephalography at rest.

63 Magnetoencephalography at t3 demonstrated significant di

64 Using magnetoencephalography-based decoding, we examined which

65 (measured by fMRI or electroencephalography/magnetoencephalography) by taking into account inter-are

66 l dementia, and show for the first time that magnetoencephalography can be used to study cognitive sy

67 r circuits, while electroencephalography and magnetoencephalography can now record cortical neural sy

68 owever, recent data now indicate that single magnetoencephalography cluster is associated with better

69 Magnetoencephalography data acquired throughout training

70 A network analysis of the magnetoencephalography data associated with this improve

71 rward and feedback parameters replicated the magnetoencephalography data faithfully.

72 er investigate this phenomenon, we collected magnetoencephalography data from 12 patients with carpal

73 ng fMRI, combined electroencephalography and magnetoencephalography data localized the ERN to the pos

74 lyzed brain functional networks derived from magnetoencephalography data recorded during working-memo

75 We tested these model predictions using magnetoencephalography data recorded from human subjects

76 xt, we compared these model predictions with magnetoencephalography data recorded while participants

77 Magnetoencephalography data were acquired during a leg f

78 Magnetoencephalography data were collected while partici

79 To bridge this gap, we recorded magnetoencephalography data while participants performed

80 In behavioural and magnetoencephalography data, we show that memory replay

81 and), using multivariate pattern analysis of magnetoencephalography data.

82 functional MRI, electroencephalography, and magnetoencephalography data.

83 These magnetoencephalography-derived measures were correlated

84 of the subthalamic nucleus and cortex using magnetoencephalography (during concurrent subthalamic nu

85 ith functional magnetic resonance imaging or magnetoencephalography (e.g., cochlear implant users).

86 phenomena, measured in humans by electro- or magnetoencephalography (EEG/MEG).

87 We recorded magnetoencephalography, EEG, and functional MRI (fMRI) w

88 Results from magnetoencephalography/EEG studies using near-threshold

89 Previous magnetoencephalography/electroencephalography (M/EEG) st

90 -matched healthy controls underwent the same magnetoencephalography/electroencephalography protocol o

91 roencephalography (EEG) and a 1-hour resting magnetoencephalography exam with simultaneous EEG.

92 Novel predictions are presented, and a new magnetoencephalography experiment in healthy human subje

93 In a magnetoencephalography experiment involving auditory tem

94 In three magnetoencephalography experiments, we recorded from non

95 -sectional sample, we recorded resting-state magnetoencephalography from 134 children and adolescents

96 We recorded magnetoencephalography from 20 adult human participants

97 Patients displaying greater magnetoencephalography global cost-efficiency, a measure

98 Magnetoencephalography has long held the promise of prov

99 The introduction of magnetoencephalography has made it possible to study ele

100 and (8-13 Hz) oscillations, as recorded with magnetoencephalography, has been previously shown to var

101 More recent publications on magnetoencephalography have added to the literature of i

102 Electroencephalography and magnetoencephalography have limited spatial resolution,

103 We recorded magnetoencephalography in 19 humans while they performed

104 Here we used Magnetoencephalography in a memory paradigm assessing co

105 In brief, we used magnetoencephalography in combination with eye-tracking

106 Here, using magnetoencephalography in combination with machine learn

107 To address this problem, we recorded magnetoencephalography in healthy participants performin

108 resting-state oscillatory connectivity using magnetoencephalography in healthy young humans (N = 183)

109 Here, we show with high-resolution magnetoencephalography in human observers (men and women

110 The present study used magnetoencephalography in human subjects to identify the

111 We measured brain activity using magnetoencephalography in humans exposed to auditory seq

112 We used magnetoencephalography in humans to investigate changes

113 Here, we used magnetoencephalography in humans to pinpoint the factors

114 Via magnetoencephalography in humans, we show in two experim

115 ve electrophysiology (electroencephalography/magnetoencephalography) in patient populations with prec

116 rossing with a functional approach, based on magnetoencephalography, in 10 dyslexic individuals who a

117 he clinical electroencephalography (EEG) and magnetoencephalography literature.

118 oiting the high temporal resolution power of magnetoencephalography, Liu et al. show in humans how "o

119 These temporal magnetoencephalography measures are novel markers of neu

120 petition and stimulus expectation and, using magnetoencephalography, measuring the neural response ov

121 visual, or auditory stimuli during the same magnetoencephalography (MEG) acquisition.

122 Using magnetoencephalography (MEG) and a tactile temporal disc

123 We used magnetoencephalography (MEG) and electroencephalography

124 uctures can be recorded noninvasively, using magnetoencephalography (MEG) and electroencephalography

125 Here we acquired human magnetoencephalography (MEG) and functional magnetic res

126 Here, we address this question using human magnetoencephalography (MEG) and multivariate analyses o

127 es based on electroencephalography (EEG) and magnetoencephalography (MEG) are unique in their ability

128 f action was assessed using gamma power from magnetoencephalography (MEG) as a proxy measure for home

129 The efficacy of magnetoencephalography (MEG) as an alternative to invasi

130 We recorded neural activity with magnetoencephalography (MEG) before and while participan

131 We used magnetoencephalography (MEG) combined with continuous th

132 nd action-associated sounds, and we recorded magnetoencephalography (MEG) data as participants adapte

133 rn analysis, or "brain decoding", methods to magnetoencephalography (MEG) data has allowed researcher

134 amics that underlie auditory processing from magnetoencephalography (MEG) data in a cocktail party se

135 Magnetoencephalography (MEG) data was acquired from heal

136 general and powerful technique for analysing Magnetoencephalography (MEG) data.

137 roscale resolution from source-reconstructed magnetoencephalography (MEG) data.

138 MRI) and localization of sources detected by magnetoencephalography (MEG) during identical language t

139 Next, we designed a magnetoencephalography (MEG) experiment to measure the n

140 rwent standard pre-surgical workup including magnetoencephalography (MEG) followed by resective surge

141 ional MRI and preferentially synchronized in magnetoencephalography (MEG) for stimuli with strong con

142 te brain activity recorded using noninvasive magnetoencephalography (MEG) from 124 healthy human subj

143 ir relationship to resting-state whole-brain magnetoencephalography (MEG) gamma power 6-9 h post-infu

144 Magnetoencephalography (MEG) imaging examined the neural

145 We examined gamma oscillations using magnetoencephalography (MEG) in children undergoing CRT

146 slow (< 5 Hz) cortical dynamics recorded by magnetoencephalography (MEG) in human subjects performin

147 We address this question by capitalising on magnetoencephalography (MEG) in humans who made choices

148 tional magnetic resonance imaging (fMRI) and magnetoencephalography (MEG) in the same group of subjec

149 Magnetoencephalography (MEG) is an increasingly popular

150 Magnetoencephalography (MEG) is an invaluable tool to st

151 We found that cortical activity measured by magnetoencephalography (MEG) is near critical and organi

152 odulation of gamma-band activity measured by magnetoencephalography (MEG) or electroencephalography (

153 to native Mandarin speakers while conducting magnetoencephalography (MEG) recording.

154 To allow wearable magnetoencephalography (MEG) recordings to be made on un

155 Whole-head magnetoencephalography (MEG) recordings were collected w

156 Using intracranial and magnetoencephalography (MEG) recordings, we show that sa

157 Using human magnetoencephalography (MEG) responses to a 2-talker mix

158 A 151-channel magnetoencephalography (MEG) scanner was used to record

159 ncy analysis of neural responses obtained by magnetoencephalography (MEG) shows that for maskers with

160 6-17 years were studied with a whole-cortex magnetoencephalography (MEG) system using a word recogni

161 lthy adults were studied using a 275-channel magnetoencephalography (MEG) system.

162 new technologies have emerged promising new Magnetoencephalography (MEG) systems in which the sensor

163 fabrication of a new generation of wearable magnetoencephalography (MEG) technology with the potenti

164 Here we show using magnetoencephalography (MEG) that tactile stimulation pr

165 We used magnetoencephalography (MEG) to assess plasticity of hum

166 n, a study by Michalareas et al. (2016) uses magnetoencephalography (MEG) to characterize the hierarc

167 We used magnetoencephalography (MEG) to examine cortical reorgan

168 In this study we use magnetoencephalography (MEG) to examine cortical reorgan

169 Here, we used magnetoencephalography (MEG) to investigate neural oscil

170 This work used magnetoencephalography (MEG) to investigate the degree o

171 We used magnetoencephalography (MEG) to investigate the frequenc

172 In the current study, we used magnetoencephalography (MEG) to investigate the primary

173 We used both non-invasive whole-head Magnetoencephalography (MEG) to look at theta oscillatio

174 In early adulthood, participants underwent magnetoencephalography (MEG) to measure neuronal activit

175 We used magnetoencephalography (MEG) to measure participants' br

176 Here, we used magnetoencephalography (MEG) to measure the time course

177 We use magnetoencephalography (MEG) to monitor brain oscillatio

178 We use magnetoencephalography (MEG) to show that disruption of

179 We investigated this question by using magnetoencephalography (MEG) to study human subjects whi

180 The application of conventional cryogenic magnetoencephalography (MEG) to the study of cerebellar

181 monitored continuous speech processing with magnetoencephalography (MEG) to unravel the principles o

182 To explain gating of memory encoding, magnetoencephalography (MEG) was analyzed over multi-reg

183 Magnetoencephalography (MEG) was recorded during a pictu

184 Resting-state magnetoencephalography (MEG) was used to assess whether

185 High-density magnetoencephalography (MEG) was utilized to evaluate th

186 In the present study, EEG and magnetoencephalography (MEG) were used to examine paired

187 Here, we recorded magnetoencephalography (MEG) while human subjects perfor

188 Magnetoencephalography (MEG) with an established index o

189 and their role in scene analysis, we combine magnetoencephalography (MEG) with behavioral measures in

190 Here we combine human magnetoencephalography (MEG) with behavioural and neural

191 Here, we combined human magnetoencephalography (MEG) with multivariate decoding

192 ing state brain networks independently using magnetoencephalography (MEG), a neuroimaging modality th

193 Magnetoencephalography (MEG), a non-invasive technique f

194 combination of electroencephalography (EEG), magnetoencephalography (MEG), and functional magnetic re

195 Combining human magnetoencephalography (MEG), computational modeling, an

196 Using the high temporal resolution of magnetoencephalography (MEG), during a rapid serial visu

197 oxygen level-dependent (BOLD) measures, and magnetoencephalography (MEG), implemented during resting

198 pain of ingroup/outgroup protagonists using magnetoencephalography (MEG), one-on-one positive and co

199 Using magnetoencephalography (MEG), we demonstrate that stimul

200 In two experiments using magnetoencephalography (MEG), we investigated motor brai

201 Using high-precision magnetoencephalography (MEG), we show that during the cl

202 Using magnetoencephalography (MEG), we show that the reduced a

203 Using magnetoencephalography (MEG), we show that this stress-i

204 of object recognition under occlusion, using magnetoencephalography (MEG), while participants were pr

205 we contrast these two theories in a parallel magnetoencephalography (MEG)-intracranial electroencepha

206 G) in healthy children and adolescents using magnetoencephalography (MEG).

207 ed with a traditional oddball paradigm using magnetoencephalography (MEG).

208 terns, while recording neural activity using magnetoencephalography (MEG).

209 is gap using the spatiotemporal precision of magnetoencephalography (MEG).

210 ) and healthy comparison subjects (HC) using magnetoencephalography (MEG).

211 th functional magnetic resonance imaging and magnetoencephalography (MEG).

212 tional magnetic resonance imaging (fMRI) and magnetoencephalography (MEG).

213 erformed a verbal working memory task during magnetoencephalography (MEG).

214 ined magnetic field amplitude, measured with magnetoencephalography (MEG).

215 e scanned with functional MRI (fMRI) (N=85), magnetoencephalography (N=33), or both (N=63) during a r

216 We revealed a clear magnetoencephalography neural signature of figure-ground

217 ng functional magnetic resonance imaging and magnetoencephalography neuroimaging data with model-base

218 Magnetoencephalography of healthy human participants dur

219 e.g., magnetic resonance imaging methods and magnetoencephalography-or been restricted to biophysics

220 wing reduced phase coupling in schizophrenia magnetoencephalography participants overlapped substanti

221 ties, conducted with electroencephalography, magnetoencephalography, proton magnetic resonance spectr

222 uman subjects using anatomically constrained magnetoencephalography, psychophysical measurements, and

223 and identified the stimuli while undergoing magnetoencephalography recording.

224 Magnetoencephalography recordings (15 ASD, 15 control su

225 Functional MRI and magnetoencephalography recordings conjointly revealed th

226 auditory cortex.SIGNIFICANCE STATEMENT Using magnetoencephalography recordings from human listeners i

227 Here, using magnetoencephalography recordings from men and women, we

228 In magnetoencephalography recordings from presurgical epile

229 Using magnetoencephalography recordings in healthy human volun

230 Magnetoencephalography recordings of neural oscillations

231 We used magnetoencephalography recordings of spontaneous activit

232 Magnetoencephalography recordings were obtained in 12 su

233 n turn informed beamforming of resting-state magnetoencephalography recordings.

234 concurrent measures of brain activity using magnetoencephalography reveal an early (350 ms) but sust

235 Magnetic resonance imaging and magnetoencephalography revealed enlarged Heschl's gyri a

236 ate that measures derived from resting-state magnetoencephalography (rsMEG) are sensitive to cortical

237 ity processing and convincingly deliver upon magnetoencephalography's promise to resolve brain signal

238 uroimaging evidence on brain circuit models, magnetoencephalography, scalp electroencephalography, an

239 ance on a working memory task performed in a magnetoencephalography scanner.

240 Neural activity was recorded during magnetoencephalography scanning while participants were

241 Magnetoencephalography showed that the association betwe

242 n-machine interface (BMI) based on real-time magnetoencephalography signals to reconstruct affected h

243 (GBO) observed in electroencephalography and magnetoencephalography signals.

244 e imaging (MSI), a noninvasive test based on magnetoencephalography source localization, can suppleme

245 lectroencephalography surface recordings and magnetoencephalography source reconstructions), both acr

246 vious quantitative electroencephalography or magnetoencephalography studies because most of the 14 br

247 Our previous human magnetoencephalography studies revealed that the subject

248 resonance imaging, electro-encephalogram, or magnetoencephalography studies, or may be more subtly co

249 This magnetoencephalography study aimed at characterizing age

250 A magnetoencephalography study was conducted using a combi

251 Unlike previous work, in this magnetoencephalography study we selected a group of pati

252 basis of inhibitory control, we conducted a magnetoencephalography study where human participants pe

253 In this magnetoencephalography study, subjects had to attend a s

254 In this magnetoencephalography study, we show that during visual

255 In this magnetoencephalography study, we tested a prediction der

256 By combining fMRI and magnetoencephalography, the location and time window of

257 er methods such as electroencephalography or magnetoencephalography to better understand the vascular

258 e used a combination of machine learning and magnetoencephalography to characterise neural dynamics i

259 uman pallidum simultaneously with whole head magnetoencephalography to characterize functional connec

260 al oscillations mediate connectivity, we use magnetoencephalography to elucidate networks that repres

261 To disentangle these possibilities, we used magnetoencephalography to evaluate how cortical activity

262 We used magnetoencephalography to examine behavioural variant fr

263 To this end, we utilized magnetoencephalography to identify changes in the alpha

264 We used magnetoencephalography to investigate interregional inte

265 We used magnetoencephalography to investigate phase synchrony be

266 ans while recording neural oscillations with magnetoencephalography to investigate the expression and

267 We used magnetoencephalography to measure neural activity while

268 e process by which this is achieved, we used magnetoencephalography to measure spatiotemporal pattern

269 We used magnetoencephalography to measure task-related local fun

270 To test this, we used magnetoencephalography to probe whether stimulus locatio

271 -duration images was combined with recording magnetoencephalography to quantify differences among per

272 This study used magnetoencephalography to record oscillatory activity in

273 measurements of brain activity obtained with magnetoencephalography to reverse-engineer a geometry of

274 Using magnetoencephalography to study healthy human participan

275 crocircuits that accurately reproduced human magnetoencephalography, to quantify network dynamics and

276 easured spontaneous cortical oscillations by magnetoencephalography together with polysomnography, an

277 Magnetoencephalography, volumetric MRI, and diffusion te

278 Magnetoencephalography was used to determine the directi

279 Here, magnetoencephalography was used to quantify the effects

280 Using magnetoencephalography, we assess spectral, temporal, an

281 Using magnetoencephalography, we continuously recorded eightee

282 Using magnetoencephalography, we demonstrate anatomically dist

283 ired by the minimal phrase "red boat." Using magnetoencephalography, we examined activity in humans g

284 With magnetoencephalography, we examined beta-band oscillator

285 Using magnetoencephalography, we further show how temporal exp

286 Using magnetoencephalography, we measured changes in the SI mu

287 Using magnetoencephalography, we quantitatively assessed devia

288 Using magnetoencephalography, we recorded the cortical activit

289 Using magnetoencephalography, we show that a representation of

290 enhanced temporal and spatial resolution of magnetoencephalography, we show that changes in alpha po

291 Using magnetoencephalography, we show that heartbeat-evoked re

292 ndividuals with autism and in controls using magnetoencephalography, which allowed us to resolve both

293 eling to model neural activity recorded with magnetoencephalography while 14 healthy humans named two

294 n and recalibration, we measured whole-brain magnetoencephalography while human participants performe

295 We recorded magnetoencephalography while human subjects (both sexes)

296 We recorded neural activity using magnetoencephalography while subjects viewed variants of

297 nd then recorded their neural activity using magnetoencephalography while they completed an object re

298 Using dynamic causal modeling for magnetoencephalography with (male and female) human part

299 The successful integration of pharmaco- magnetoencephalography with dynamic causal models of fro

300 ng functional magnetic resonance imaging and magnetoencephalography with humans that novel task prepa