ライフサイエンスコーパス: functional imaging

1 ation of in vivo fast tracer kinetics during functional imaging.

2 e decline in left ventricular performance by functional imaging.

3 studies using covert speech and haemodynamic functional imaging.

4 m these studies, to complement evidence from functional imaging.

5 basis of BOLD (blood-oxygen-level-dependent) functional imaging.

6 invasive nonhuman primate studies and human functional imaging.

7 Twenty patients had typical seizures during functional imaging.

8 nt from disease progression by incorporating functional imaging.

9 t has not yet been compared with traditional functional imaging.

10 tumor kinetics, radiomics, and molecular and functional imaging.

11 exercise physiology, and both structural and functional imaging.

12 igh-throughput applications based on in vivo functional imaging.

13 According to functional imaging, a gradual return of evoked whisker f

14 Functional imaging also shows that TSC patients with ASD

15 Noninvasive functional imaging analyses derived from coronary comput

16 e converging evidence from three independent functional imaging and behavioral studies.

17 Functional imaging and behavioral tasks included face-em

18 Here we combine functional imaging and computational modeling to identif

19 While functional imaging and deep brain stimulation studies po

20 Through functional imaging and electrophysiological studies, muc

21 g digitalized multiparametric anatomical and functional imaging and enhance the ability to precisely

22 been made in brain imaging, especially with functional imaging and fibre tracking with the use of di

23 MRI, which is used for functional imaging and for the diagnosis of a broad rang

24 Functional imaging and gene expression studies both impl

25 Through functional imaging and genetic inactivation of specific

26 Here we use functional imaging and human single-neuron recordings to

27 lumn lesions and reveals differences between functional imaging and microelectrode recording maps.

28 -activity measurements as provided by modern functional imaging and neuronal recording techniques.

29 We have also applied our method to functional imaging and neuropixels recordings from the m

30 Evidence from human functional imaging and neuropsychology, and monkey neuro

31 w advanced microscopy techniques for in vivo functional imaging and offer guidelines for which techno

32 Functional imaging and psychometric assessments indicate

33 ent of implantable light sources that enable functional imaging and sensing in freely moving animals.

34 Advanced MRI and functional imaging and subsequent intracranial EEG confi

35 eal time during surgery can lead to improved functional imaging and surgical outcomes, respectively.

36 ysis provides the underpinning to understand functional imaging and the effect of penetrating vessels

37 kinesia, findings that are in agreement with functional imaging and transcranial magnetic stimulation

38 Finally, consistent with prior findings from functional imaging and transcranial magnetic stimulation

39 Functional imaging and translational profiling experimen

40 Heritability, functional imaging, and gene expression studies of AT in

41 rement of artifacts and nonneural effects in functional imaging, and more recently, the study of biop

42 ion of multiple targeted neurons, volumetric functional imaging, and quantitative behavioral tracking

43 approaches: localizing candidate areas using functional imaging, and showing that interference with t

44 dvances in genetics, blood-based biomarkers, functional imaging, and systemic therapy of advanced NET

45 including cross-sectional anatomic imaging, functional imaging, and transoral surgical techniques, d

46 Here, we used a multi-modality functional imaging approach to identify these mechanisms

47 Here, we use a functional imaging approach to reveal dynamic changes in

48 Functional imaging approaches reliably identify underlyi

49 Functional imaging approaches strive to noninvasively es

50 Parallel developments in functional imaging are providing additional potential to

51 There have been major advances in functional imaging as well, one of which is the applicat

52 ation and advances in magnetic resonance and functional imaging, as well as from the emergence of bio

53 ses, clinical, biochemical, pathological and functional imaging assessments can all contribute to mor

54 t case, scanning children with diffusion and functional imaging at age 5, before they learned to read

55 intact adult zebrafish allows structural and functional imaging at cellular resolution throughout the

56 Thirty-three women underwent functional imaging at four time points (123 total scans)

57 Here, we combine ultra-high-field (7T) functional imaging at sub-millimeter resolution with ori

58 py to address the challenges associated with functional imaging at this developmental stage, we recor

59 Here, we present data from functional imaging, behavioral epistasis, and unilateral

60 Such functional imaging biomarker in combination with LA volu

61 elerated PAT applications in signal sensing, functional imaging, biomarker labeling and therapy monit

62 Interim restaging with functional imaging by positron emission tomography using

63 This study shows that MRI-based functional imaging can detect apoptotic responses to MYC

64 f tumorigenesis, longitudinal anatomical and functional imaging can enhance the scope of studies by f

65 e structural state of muscle sarcomeres, SHG functional imaging can give insight into the integrity o

66 raphy (PET), combine the superb anatomic and functional imaging capabilities of MR imaging with the u

67 l platform to develop new multimolecular and functional imaging capabilities.

68 The single-RBC functional imaging capability of FOG enables numerous bi

69 solution, multiplanar image acquisition, and functional imaging capability through specialized techni

70 The functional imaging capacity of 3D-wPAT was demonstrated

71 We evaluated morphologic and functional imaging characteristics to elucidate evidence

72 tergic and gamma-aminobutyric acidergic) and functional imaging correlates associated with such an ef

73 This review proposes that although the functional imaging data are statistically valid in most

74 strategies during simultaneous collection of functional imaging data at seven tesla.

75 eled pulmonary ventilation was compared with functional imaging data from breath-hold time-series (12

76 Meta-analyses of functional imaging data indicate that cortical correlate

77 We then examined functional imaging data recorded during task performance

78 with hypersexuality were OFF medication, the functional imaging data showed decreases in activation d

79 The functional imaging data showed that the hypersexuality p

80 While both anatomical and functional imaging data suggest that the influence of tr

81 The functional imaging data were analysed using statistical

82 fications of standard methods of analysis of functional imaging data.

83 Conclusion: Structural and functional imaging demonstrated regional heterogeneities

84 Functional imaging demonstrates that DPM activation evok

85 Moreover, functional imaging disclosed a LH region tuned to repuls

86 enables in vivo two-photon morphological and functional imaging down to 700 mum inside the mouse brai

87 manifestation of tics cannot be captured via functional imaging due to motion artefacts and limited t

88 imaging of the DA system is integrated with functional imaging during cognitive performance have yie

89 28) and control subjects (n = 28) underwent functional imaging during performance of a monetary ince

90 Second, functional imaging during speed-matched execution of tra

91 have further characterized the SINs through functional imaging, electrophysiological recordings, and

92 n oxygen saturation (i.e., oxygenation) is a functional imaging endpoint that can reveal variations i

93 problem by providing real-time anatomic and functional imaging, even through intact peritoneum.

94 preclinical rodent model, there is still no functional imaging evidence supporting DMN deactivation

95 In vivo functional imaging experiments further demonstrate disru

96 e that Cal-590 is also suited for multicolor functional imaging experiments in combination with other

97 nalytic approach incorporating more than 100 functional imaging experiments, we show that preference

98 be readily used for simultaneous multicolor functional imaging experiments.

99 senting a potential artifact during neuronal functional imaging experiments.

100 Using functional imaging (fMRI), we found that the ventromedia

101 somatosensory cortex using psychophysics and functional imaging (fMRI).

102 tools, including high-resolution hemodynamic functional imaging, focused ultrasound neuromodulation,

103 rticle, we compare the roles of anatomic and functional imaging for cardiac device infection and disc

104 ensity-modulated radiotherapy) combined with functional imaging for more precise delineation of targe

105 Functional imaging, for example, of intracellular calciu

106 proach has the potential to enable lens-less functional imaging from within the brain itself to achie

107 applicability of VSD imaging for real-time, functional imaging guidance during nerve-sparing radical

108 treatment and how do they compare with other functional imaging-guided paradigms?

109 Functional imaging has applications in clinical trials t

110 Functional imaging has revealed both distinct characteri

111 Functional imaging has shown that these patches are acti

112 imaging systems, which combine anatomic and functional imaging, has revolutionized diagnostic imagin

113 clerosis by serial noninvasive molecular and functional imaging, histopathology, and a pharmaceutical

114 Noninvasive functional imaging holds great promise for serving as a

115 s and with blood oxygenation level-dependent functional imaging in 35 healthy participants from the A

116 t hippocampal circuit function, we performed functional imaging in acute slices and targeted eloquent

117 r patients with suspected PD, the benefit of functional imaging in atypical parkinsonism syndromes re

118 as well as the potential for multiparametric functional imaging in conjunction with PET.

119 also present spatially isotropic whole-brain functional imaging in Danio rerio larvae and spatially i

120 y reinforces the potential role of MRI-based functional imaging in delivering precision medicine to c

121 New research establishes that high-field functional imaging in humans can distinguish laminar spe

122 ter embryos and perform adaptive whole-brain functional imaging in larval zebrafish.

123 he concepts and strategies of structural and functional imaging in living cells at the single-molecul

124 for clinical symptoms, and changes of brain functional imaging in SCA38 patients.

125 filling" of the dye to the soma, followed by functional imaging in the labeled cell.

126 We applied MPAO to in vivo structural and functional imaging in the mouse brain.

127 ise to the population response observed with functional imaging in the parahippocampal place area.

128 the host plant Datura wrightii and performed functional imaging in the primary olfactory center of M.

129 on of dopaminergic neurons with postsynaptic functional imaging in vivo.

130 and expanded neural tissues and high-speed, functional imaging in vivo.

131 maging measures (magneto-encephalography and functional imaging) in a group of early deaf humans.

132 rine tumors (NETs) occult on morphologic and functional imaging, in relation to tumor origin and diff

133 Functional imaging included standard cinematic imaging t

134 nly studied task scenario in single-unit and functional imaging investigations, have not been establi

135 emonstrate that low-cost fluorescence kidney functional imaging is highly sensitive and useful for th

136 ential diagnosis of degenerative dementia if functional imaging is indicated.

137 Integrated structural and functional imaging is recommended to characterize adrena

138 In functional imaging, large numbers of neurons are measure

139 A novel functional imaging mass spectrometry technology is descr

140 s suggest that multiparametric molecular and functional imaging may be capable of providing comprehen

141 ional or compensatory circuits identified by functional imaging, may take neuroimaging into a new, th

142 Electroencephalogram (EEG) and functional imaging measures in clinical studies have pre

143 PET is a functional imaging method that can exploit various aspec

144 We present a deep tissue multiplexed functional imaging method that probes multiple Forster r

145 Lung EIT is a functional imaging method that utilizes electrical curre

146 works have been emphasized by development of functional imaging methods for correlating activity acro

147 Recent improvements in both morphologic and functional imaging methods have contributed immensely to

148 Functional imaging methods such as fMRI have been widely

149 ildtype mice by histological, molecular, and functional imaging methods.

150 In tinnitus, PET and other functional imaging modalities have shown functional chan

151 nd signal suppression (DWIBS) are 2 powerful functional imaging modalities in the evaluation of malig

152 with anatomic imaging with CT/MRI and other functional imaging modalities, including (18)F-fluorohyd

153 Morphologic and functional imaging modalities, such as CT and MRI, have

154 with 227 metastases iodine-positive on both functional imaging modalities.

155 Photoacoustics is a non-ionizing, functional imaging modality capable of high contrast ima

156 Ga-DOTATATE PET/CT will become the preferred functional imaging modality for HNPGLs in the near futur

157 y was to assess the clinical utility of this functional imaging modality in parasympathetic head and

158 disease, this technique is now the preferred functional imaging modality to evaluate and to monitor t

159 studies presents an emerging need for a new functional imaging modality.

160 Using functional imaging, modeling, and EM reconstruction, we

161 We combined high-resolution structural-functional imaging, molecular assays for neurotransmitte

162 beric acid ((18)F-FASu), as a PET tracer for functional imaging of a cellular response to oxidative s

163 nsic two-photon excited fluorescence enables functional imaging of adipocyte metabolism with subcellu

164 oscopy techniques that enable structural and functional imaging of biological specimens at unpreceden

165 We propose a new paradigm for dense functional imaging of brain activity to surmount the lim

166 d illumination microscopy (SIM), has enabled functional imaging of cellular and subcellular organelle

167 synthesis of published work, with a focus on functional imaging of circuit dysfunctions across the sp

168 e applications in real-time and postsurgical functional imaging of collagen-rich tissues subjected to

169 al apparatus that allows cellular resolution functional imaging of cortical regions during epochs of

170 escribe a technique that allows for chronic, functional imaging of dentate gyrus granule cells in awa

171 We demonstrate whole-animal functional imaging of Drosophila larvae at a spatial res

172 berration correction improved structural and functional imaging of fine neuronal processes over a lar

173 lug-and-play microscope heralds a new era in functional imaging of freely behaving animals.

174 axonal boutons in the mouse hippocampus, and functional imaging of GABAergic neurons in the mouse lat

175 on microscopy at 1,300-nm excitation enables functional imaging of GCaMP6s-labeled neurons beyond the

176 Functional imaging of head-fixed, behaving mice using tw

177 tional empathy have been widely studied with functional imaging of healthy participants.

178 ) PET/CT, currently the gold standard in the functional imaging of HNPGLs.

179 technique that was originally developed for functional imaging of kidney microvilli and enables dete

180 offers three-dimensional (3D) structural and functional imaging of living biological tissue with labe

181 eveloped a technique for cellular-resolution functional imaging of medial entorhinal cortex (MEC) neu

182 Noninvasive functional imaging of molecular and cellular processes o

183 Functional imaging of neural activity in the processes o

184 Using genetics and functional imaging of neural activity we characterize th

185 combined electron microscopy reconstruction, functional imaging of neural activity, and behavioral ex

186 111)In-pentetrotide SPECT have been used for functional imaging of neuroendocrine tumors (NETs) for t

187 Here we demonstrate simultaneous functional imaging of neuronal activity at single-neuron

188 This approach can be broadly applicable to functional imaging of other brain structures.

189 Our approach can be broadly applicable to functional imaging of other core brain structures.

190 ed a metabolically activated radiotracer for functional imaging of P-gp/BCRP activity with positron e

191 Functional imaging of proteolytic activity is an emergin

192 y combining odor discrimination studies with functional imaging of sensory input activity in awake mi

193 Label-free functional imaging of single red blood cells (RBCs) in v

194 nt of molecular MRI methods that could allow functional imaging of the brain by sensing the neurotran

195 hy is a promising, noninvasive technique for functional imaging of the mouse brain.

196 Feasibility of simultaneous PET/MRI functional imaging of tumors was explored by following (

197 uted tomography (microCT) for anatomical and functional imaging of vascular alterations in three muri

198 short echo time MRI in the lungs allowed for functional imaging of ventilation inhomogeneity within a

199 ing viral trans-synaptic circuit mapping and functional imaging of visually driven calcium signals in

200 y properties of monocytes and macrophages by functional imaging on explanted lungs.

201 uits in freely behaving worms by integrating functional imaging, optogenetic interrogation, genetic m

202 from behavioral analysis and two independent functional imaging paradigms that a single session of at

203 ient was used to assess correlations between functional imaging parameters.

204 nts were used to assess correlations between functional imaging parameters.

205 ge- (gastroscopy, EUS, and anatomical and/or functional imaging) positive or image negative disease.

206 us endocarditis (IE) can be improved through functional imaging procedures such as radiolabeled leuko

207 Single-cell RNA-sequencing and in vivo functional imaging provide expansive but disconnected vi

208 This work reveals a new approach to functional imaging, providing a robust platform for inve

209 METHOD: Functional imaging responses to three paradigms-the stop

210 Behavioral and functional imaging results were compared between groups

211 ung adults were assessed in an event-related functional imaging scan while performing the 'AX'-contin

212 In subsequent functional imaging sessions they were exposed to trials

213 s combining electrical microstimulation with functional imaging showed an interconnected set of regio

214 Functional imaging shows that some of the Odd neurons re

215 pling underlies blood oxygen level-dependent functional imaging signals, but its mechanism is controv

216 ors of cerebral blood flow and initiators of functional imaging signals.

217 Because the functional imaging signature of patients with PPGL-polyc

218 Therefore, novel molecular and functional imaging strategies are urgently required.

219 Furthermore, they suggest a unique functional imaging strategy based on pH that is independ

220 Recent data derived from anatomic and functional imaging studies are providing new insights in

221 Thus, some functional imaging studies find that subcortical anomali

222 n recent neurophysiological, behavioral, and functional imaging studies from the nonhuman primate tha

223 Furthermore, lesion and functional imaging studies have contributed little knowl

224 Functional imaging studies have demonstrated that cognit

225 Recent functional imaging studies have proposed that the human

226 Functional imaging studies have revealed that certain br

227 Stimulation and functional imaging studies have revealed the existence o

228 Functional imaging studies have shown that early process

229 Since functional imaging studies have shown that homologous co

230 ogical studies in other aphasic cohorts, and functional imaging studies in healthy controls.

231 T raises significant technical obstacles for functional imaging studies in humans.

232 patterns of dysfunction, a meta-analysis of functional imaging studies of emotion was undertaken.

233 Functional imaging studies of healthy participants and p

234 haracterizing dopaminergic transmission, and functional imaging studies of reward processing and gamb

235 ome increasingly well defined as a result of functional imaging studies of thermogenically active BAT

236 However, functional imaging studies reveal correlations between a

237 In the brain, functional imaging studies reveal diffuse activation map

238 Basic and functional imaging studies suggest a role for prefrontal

239 Functional imaging studies suggest that intrinsic "resti

240 be considered when interpreting findings of functional imaging studies that rely of estimates of neu

241 its of emotion and motivation highlighted by functional imaging studies, have shown promising effects

242 Here, in agreement with human functional imaging studies, we found that 26% of neurons

243 onnectivity foundation for interpretation of functional imaging studies, which often indicate activit

244 Functional imaging studies, which similarly tend to find

245 This functional imaging study assessed domain-general activit

246 ormal tissues is predicted using anatomic or functional imaging, such as in the use of CT or PET to p

247 We developed an integrated multi-functional imaging system, in which synchronized dual wa

248 solidly replicable regardless of the applied functional imaging technique.

249 These functional imaging techniques are used in detection of i

250 taging of disease in these patients, whereas functional imaging techniques are useful both for detect

251 l role in trials, structural, molecular, and functional imaging techniques can give us a window on th

252 Over the past 2 decades, functional imaging techniques have become commonplace in

253 retina and choroid has made great progress, functional imaging techniques have been lacking.

254 Functional imaging techniques provide information on tum

255 rtic disease is more fully revealed with new functional imaging techniques than with conventional ana

256 Modern imaging techniques, particularly functional imaging techniques that interrogate some spec

257 This vascular signal is used by functional imaging techniques to infer the location and

258 Here, we use circuit mapping and in vivo functional imaging techniques to trace gustatory and olf

259 view will discuss the current structural and functional imaging techniques used for the diagnosis of

260 With advances in anatomic and functional imaging techniques, we now have tools for ass

261 Applied to the spine, "functional" imaging techniques such as MR spectroscopy,

262 Using the in vivo functional imaging technology DREAMM (DREADD-assisted me

263 (7) how will CT-FFR influence other functional imaging test utilization, and what will be th

264 and the strategies in using advanced MRI and functional imaging tests and their associated postsurgic

265 x exhibits a sensitivity to reaction time on functional imaging that is consistent with such a mechan

266 suggesting the potential of SS-ODT for brain functional imaging that requires high flow sensitivity a

267 The applications of molecular and functional imaging that would enable a whole-body "holis

268 Before presentation during functional imaging, the clips were evaluated by age-matc

269 This combination of structural and functional imaging therefore highlights the contribution

270 Workers are investigating the role of functional imaging to assess whether treatment can be ta

271 sess reader confidence after the addition of functional imaging to conventional sequences.

272 Here we used high-resolution functional imaging to determine the signaling patterns i

273 Here, we use in vivo functional imaging to identify a class of cutaneous sens

274 ent studies used a virtual hunting assay and functional imaging to identify prey-capture circuits in

275 We use functional imaging to identify the neural network whose

276 mbined behavior, computational modeling, and functional imaging to investigate mechanisms supporting

277 Functional imaging to monitor Ca(2+) and ERK signals rev

278 be useful in a wide range of structural and functional imaging to study the interactions between cel

279 ing and discuss the implications of applying functional imaging to visualize cancer progression and t

280 vidence, theories and methods, such as brain functional imaging, to explain the pathophysiological li

281 Lesion studies complement functional imaging, to identify areas necessary for a ta

282 (18)F-FDOPA PET appears to be a sensitive functional imaging tool for the detection of primary NET

283 Although modern functional imaging tools allow study of brain correlates

284 heir results suggest that the combination of functional imaging using fluorothymidine-positron emissi

285 mouse taste buds and taste cells, conducted functional imaging using Fura-2, and used cellular biose

286 Using functional imaging we monitored activity of the gut-brai

287 Through the use of brain-wide functional imaging, we identify three neuronal clusters

288 Anatomic and functional imaging were performed for tumor visualizatio

289 imultaneous video-electroencephalography and functional imaging will improve the localization of the

290 Accumulating data suggest that functional imaging with (18)F-FDG PET/CT has unique meri

291 omise in this respect are the application of functional imaging with (18)F-fluorodeoxyglucose positro

292 hoton excitation allowed largely independent functional imaging with a green fluorescent calcium sens

293 g a stop-signal response inhibition task and functional imaging with analysis of effective connectivi

294 herein highlight the use of nanopipettes for functional imaging with applications from cell biology t

295 Carbogen-based functional imaging with PAI and BOLD MR imaging enables

296 resolution, and enabled real-time intestinal functional imaging with ultrasound co-registration.

297 ction ready-to-use tools for deep two-photon functional imaging with unprecedentedly high and homogen

298 claim that has recently gained support from functional imaging work in humans [6-14].

299 d by the other methods-suggesting that prior functional imaging work may have significantly underesti

300 ms with technologies for cellular resolution functional imaging would provide a powerful approach to