ライフサイエンスコーパス: real-time imaging

1 ering high resolution currently do not allow real-time imaging.

2 under different stimulant concentrations by real-time imaging.

3 urately quantified by using radial k-t SENSE real-time imaging.

4 rovides high-signal, low-background and near real-time imaging.

5 sensing allowing robustness, versatility and real-time imaging.

6 tumor-specific replication, as visualized by real-time imaging.

7 l opacification by MCE to be achieved during real-time imaging.

8 simple operation, no ionizing radiation, and real-time imaging.

9 ply demarcated lesions with the safeguard of real-time imaging.

10 ic transformations, enabling multicomponent, real-time imaging.

11 renal toxicity, with the great advantage of real-time imaging.

12 ng setup and software package for multicolor real-time imaging.

13 nal diagnostics and intervention by enabling real-time imaging.

14 romatid resolution and chromosome folding by real-time imaging.

15 e consuming iterative phase recovery hampers real-time imaging.

16 l science tools such as chemical biology and real-time imaging.

17 onveniently quantified by flow cytometry and real-time imaging.

18 g C3C4 droplets or C3 droplets during low MI real-time imaging.

19 colemmal repair in live zebrafish embryos by real-time imaging.

20 l filled with two fluid phases using direct, real-time imaging.

21 ng laws exhibited by the system and, through real-time imaging, address a long-standing question of w

22 e, and polymer degradation along with the CT real time imaging all consistently support the implant f

23 Real time imaging also revealed that a lipid-binding poi

24 Real-time imaging, although inferior in image quality to

25 e calcium-sensitive dye Fluo-4, we conducted real-time imaging analyses of calcium waves propagated a

26 Real time imaging analysis showed that insulin induced R

27 The label-free real-time imaging and analysis of microscale particles i

28 Using a combination of in vivo real-time imaging and blood/tissue partitioning by intra

29 gocytosis kinetics, which is compatible with real-time imaging and can be used to validate existing r

30 Results Volumetric MSOT achieved real-time imaging and characterization of the entire car

31 By combining real-time imaging and chemical-sensitive electron tomogr

32 Using real-time imaging and clonal analysis, we demonstrate th

33 ll transcript counting, genetic engineering, real-time imaging and computational modelling, we show t

34 Another challenge is to incorporate real-time imaging and develop computational approaches t

35 Real-time imaging and display at video-rate speed are cr

36 f the Alzheimer's disease Abeta peptide with real-time imaging and fluorescence correlation spectrosc

37 We have applied real-time imaging and fluorescence recovery after photob

38 Real-time imaging and functional studies revealed that t

39 They also enable high-resolution, real-time imaging and in vitro analysis of biochemical,

40 Real-time imaging and interaction modeling elucidate the

41 DASH offers the advantages of real-time imaging and no ionizing radiation and may obvi

42 Real-time imaging and photokinetics approaches indicate

43 troduce DeCalciOn, an open-source device for real-time imaging and population decoding of in vivo cal

44 GFP technology has also been used for real-time imaging and quantification of angiogenesis.

45 Here we report real-time imaging and quantification of droplet motion i

46 Here we show, with the use of real-time imaging and quantitative image analysis of Dro

47 biomarker diagnostics as well as multiplexed real-time imaging and spectroscopy.

48 Both real-time imaging and surface biotinylation have demonst

49 mal plates and rete pegs was measured during real-time imaging and the number and diameter of epiderm

50 ing Cas13 RNases (dCas13s) that allow robust real-time imaging and tracking of RNAs in live cells, ev

51 agnostics, bioterrorism agent detection, and real-time imaging and tracking of single-molecule proces

52 n interference microscope (RIM) that enables real-time imaging and tracking the Li nucleation dynamic

53 s with other cancer therapies while enabling real-time imaging and tumor tracking.

54 Using biochemistry, genetics, real-time imaging, and cell biology, we confirm that rou

55 ee-dimensions, allowing for high resolution, real-time imaging, and precise quantification of endothe

56 We developed a confocal real-time imaging approach that allows direct observatio

57 able biomarkers of endolymphatic hydrops and real-time imaging are warranted to improve understanding

58 ology and integration into a microscope for "real-time" imaging are needed to further improve this te

59 As a proof of concept, we perform continuous real-time imaging at a frame speed of 163 ns (a frame ra

60 explored due to challenges in real-space and real-time imaging at single-particle and atomic resoluti

61 eds demonstrated close correlation with both real-time imaging (b, r=0.79; Axb, r=0.81) and triggered

62 rescent biosensors can address this gap with real-time imaging, but such technologies for mammalian c

63 o both quantitative biochemical analysis and real-time imaging by epifluorescence microscopy.

64 on rate on nanoparticles in the solution via real-time imaging can be used to measure not only [e(-)a

65 ution of pentacene thin films, utilizing the real-time imaging capabilities of photoelectron emission

66 tem integrates a modular fluidic device with real-time imaging capabilities to enable the observation

67 ated working swine heart model (n = 5), with real-time imaging capabilities.

68 Mitochondrial function was monitored by real-time imaging, cytochrome c redistribution, and reac

69 nalysis for different plant species based on real-time imaging data obtained from different spectra.

70 Quantification of the real-time imaging data revealed lateral branching as the

71 a clinical isolate of A. castellaniiIn vitro real-time imaging demonstrated that trophozoites of both

72 Real-time imaging devices have been widely adopted, but

73 Targeted real-time imaging during robot-assisted radical prostate

74 e in data and compute needs, which precludes real-time imaging, feedback and decision-making capabili

75 While useful for real-time imaging, few such probes are available.

76 Real-time imaging following the addition of 3.6 mm Ca(2+

77 ure of fresh tumor tissue enables convenient real-time imaging, genetic and microenvironmental manipu

78 Recent multidisciplinary efforts combining real-time imaging, genome sequencing, and biophysical st

79 y (PACT), enabling nanoparticle tracking and real-time imaging-guided PTT in deep tissues.

80 Its real-time imaging-guided stimulation strategy with a sin

81 l in biological systems, and biosensor-based real-time imaging has revolutionized their analysis.

82 Advances in real-time imaging have refined our understanding of the

83 recent advances in cell lineage analysis and real-time imaging have uncovered surprising differences

84 In stent-implanted vessels, real-time imaging illuminated an edge-based pattern of s

85 ffer from photobleaching, and it allows near real-time imaging in 3D with submicrometer spatial resol

86 is therefore poised for many applications in real-time imaging in cells and whole animals.

87 ate the utility of bimodal viral vectors and real-time imaging in evaluating fate of NSCs in diseased

88 ffers exciting prospects for high-resolution real-time imaging in high-throughput environments such a

89 abolism; however, there are no analogues for real-time imaging in live cells.

90 Microirradiation and real-time imaging in living cells revealed that HMGA2 de

91 Using real-time imaging in living cultured neurons, we demonst

92 Real-time imaging in rats showed a delayed and lower upt

93 romoter demonstrated excellent activation by real-time imaging in response to local inflammation.

94 By combining immunostaining and real-time imaging in viable slices of human lung tumors,

95 ymphocytes (TIL) and T cells, as revealed by real-time imaging in vivo.

96 y improved the capabilities of non-invasive, real-time imaging in whole animals.

97 Real-time imaging in zebrafish displayed that fluorescen

98 neocortical precursor cells in situ through real-time imaging, marker analysis, and electrophysiolog

99 Laser ablation direct analysis in real time imaging-mass spectrometry (LADI-MS) was succes

100 Laser ablation direct analysis in real time imaging-mass spectrometry offers unprecedented

101 However, there is no real-time imaging method to capture biological electron

102 Using a real-time imaging method, we show that TMEM176A/B accumu

103 Using a wide-field real-time imaging method, we visualize an increase in cy

104 h limitations, we have developed single-cell real-time imaging methodology to track the formation of

105 Using these real-time imaging methods, we confirmed the immunosuppre

106 retrospectively gated cine imaging (n=37) or real-time imaging (n=63), depending on the patient's abi

107 Real time imaging of a photoactivatable green fluorescen

108 Using real time imaging of changes in phosphatidylinositol 4,5

109 emonstrate the usefulness of GFP tagging for real time imaging of G protein-coupled receptor traffick

110 phy (CT) imaging approach is used to achieve real time imaging of ISFIs in vivo and in vitro using le

111 e resonance energy transfer (FRET), allowing real time imaging of phosphorylation resulting from PKC

112 llow bright switch and enables non-invasive, real-time imaging of 17beta-HSD10 in live human cells.

113 ized the ANCHOR/ParB DNA-labeling system for real-time imaging of a single-copy, estrogen-inducible t

114 ions for amino acid synthesis as well as the real-time imaging of amino acids in biological systems.

115 and tdTomato, opening up the possibility for real-time imaging of another molecule.

116 Real-time imaging of antibody-drug conjugates (ADCs) off

117 This BAP-TM allows noninvasive real-time imaging of any cell type transduced to express

118 Applications for noninvasive real-time imaging of apoptosis and neuronal degeneration

119 eles were fluorescently tagged, we performed real-time imaging of Arc mRNA dynamics in individual neu

120 roscopy, we show the utility of this tool in real-time imaging of astrocytes in living mouse brain an

121 Real-time imaging of ATP release from astrocyte cells ha

122 cell culture and microscopy that enable the real-time imaging of axonal membrane protein trafficking

123 e describe a mobile-phone-based strategy for real-time imaging of biplexed NAATs in paper.

124 Orai1 function was assessed by real-time imaging of calcium transients as PMNs were sti

125 By real-time imaging of cAMP levels in intact myocytes and

126 e report here the development of subcellular real-time imaging of cancer cell trafficking in live mic

127 In the present report, we show real-time imaging of cancer cell trafficking in lymphati

128 ol in the arsenal of clinical cardiology for real-time imaging of cardiac dynamics.

129 n to clinical cardiology as a major tool for real-time imaging of cardiac dynamics.

130 recise control over oxygen concentration and real-time imaging of cell behavior.

131 cal application of a new phosphine probe for real-time imaging of cell-surface glycans using biolumin

132 spectroscopy, which will permit noninvasive real-time imaging of cells undergoing oxidative stress.

133 Real-time imaging of cellular and subcellular dynamics i

134 Using real-time imaging of cellular circadian gene expression

135 e expression and cellular physiology, and in real-time imaging of cellular metabolites and signals.

136 lysing the kinetics of NO receptor function, real-time imaging of cellular NO signal transduction in

137 al reflection fluorescence method capable of real-time imaging of cellular structure height with nano

138 Real-time imaging of chromosome movements in HeLa cells

139 Real-time imaging of chromosome segregation in HeLa cell

140 Using real-time imaging of circadian gene expression, a new st

141 Here, using real-time imaging of cohorts of mouse radial glia cells,

142 y of elegant approaches, including the first real-time imaging of cortical neurons with reduced level

143 Real-time imaging of countless femtosecond dynamics requ

144 Here, we report that the real-time imaging of DCIS mouse models using ICG-p28 sho

145 f forward genetic screens combined with live real-time imaging of development in transparent zebrafis

146 The AO protocol is quick, simple and allows real-time imaging of doomed cells in live tissues.

147 Such noninvasive and real-time imaging of drug-induced apoptosis in situ can

148 This methodology enables real-time imaging of dynamic metabolic status in vivo us

149 hich greatly restricts their applications in real-time imaging of dynamic scenes.

150 trated the use of AiFC for high-contrast and real-time imaging of endogenous RNA molecules in living

151 HHC was then successfully used for the real-time imaging of endogenous UGT1A1 in living cells a

152 tion process in live cells, we have employed real-time imaging of enhanced green fluorescent protein

153 e activation, we used immunofluorescence and real-time imaging of FcgammaR-induced phagocytosis.

154 To enable noninvasive real-time imaging of FFA flux in the liver, we generated

155 Real-time imaging of fluorescence resonance energy trans

156 iments involving single-molecule counting or real-time imaging of fluorescent reporter constructs.

157 Through real-time imaging of fluorescently labeled leukocytes, w

158 Using real-time imaging of fluorescently tagged Trks, we show

159 ptides are promising structures for in situ, real-time imaging of fungal infection.

160 Recently, the approach of real-time imaging of GCs by two-photon microscopy of int

161 es in a way that could be readily applied to real-time imaging of gene expression in living cells.

162 Using real-time imaging of gene expression, we found that the

163 Using noninvasive real-time imaging of genetically tagged PMNs in a murine

164 tion within a cutaneous wound, combined with real-time imaging of genetically tagged PMNs, we observe

165 Real-time imaging of glutamate transients by fluorescent

166 We sought to elucidate this mechanism using real-time imaging of growth factor-induced stratificatio

167 Real-time imaging of growth kinetics reveals that a low

168 The fast kinetics enabled real-time imaging of H(2) O(2) produced in endothelial c

169 Real-time imaging of HCV IRES luciferase reporter messen

170 Real-time imaging of immunoactivation is imperative for

171 d off by photobleaching, enabling continuous real-time imaging of integrin molecular tensions in live

172 We performed real-time imaging of intestinal peristalsis in zebrafish

173 Real-time imaging of intracellular calcium dynamics reve

174 This was combined with real-time imaging of intracellular free-calcium activity

175 d submicron spatial resolution, allowing for real-time imaging of islet blood flow within the living

176 phagocytosis in retinal development, we used real-time imaging of larval zebrafish to provide cell-ty

177 Our findings suggest that real-time imaging of leukocyte dynamics can provide new

178 Real-time imaging of live myocytes expressing green fluo

179 Real-time imaging of live myofibers during injury demons

180 er with other axonal membrane proteins using real-time imaging of live neurons.

181 Real-time imaging of live NPCs revealed lagging chromoso

182 Optical Coherence Tomography (OCT) enables real-time imaging of living tissues at cell-scale resolu

183 rotein (alpha(1)-AR/GFP) were assessed using real-time imaging of living, transiently transfected hum

184 In this study, by real-time imaging of LNs, we show that the inhibition of

185 Motivated by real-time imaging of loop extrusion (LE), we created an

186 eaction system, we report for the first time real-time imaging of lysis and leakage of single bacteri

187 transparency of larval zebrafish and perform real-time imaging of macrophage-melanoma interactions.

188 e, we established a new reporter that allows real-time imaging of membrane protein transport from the

189 We also demonstrate real-time imaging of microfluidic flow and phase-explosi

190 Real-time imaging of migrating neurons has changed our u

191 can be used to study dynamic processes with real-time imaging of molecules within 1- to 5-nm spatial

192 Real-time imaging of mouse embryos revealed EC movement

193 Real-time imaging of moving organs and tissues at micros

194 to determine the feasibility and accuracy of real-time imaging of myocardial contrast echocardiograph

195 ese results demonstrate the use of GR-GFP in real-time imaging of nuclear transport.

196 cell-cycle phase specific immunostaining and real-time imaging of PCNA expressing apical progenitors

197 rescence resonance energy transfer, allowing real-time imaging of phosphorylation catalyzed by PKB.

198 Using real-time imaging of photoconverted microtubules, we dem

199 Real-time imaging of protease activity specific to SARS-

200 Our results suggest that real-time imaging of protein dynamics is conceptually fe

201 but not by their eukaryotic hosts, to allow real-time imaging of pulmonary infections and rapid quan

202 ratiometric photoacoustic probe for in vivo real-time imaging of reactive oxygen species--vital chem

203 New and evolving techniques, including real-time imaging of second messengers, hold the promise

204 Recent developments have enabled the real-time imaging of single protein trafficking and the

205 monstrate the importance of direct-space and real-time imaging of skyrmion domains for addressing bot

206 transfer-based biosensors have made possible real-time imaging of spatial and temporal gradients of i

207 Through real-time imaging of STAP cells derived from purified ly

208 eter array, enabling high-resolution, nearly real-time imaging of subsurface quasistatic deformations

209 igen-presenting cells (APCs) were stable and real-time imaging of T cell receptor (TCR) clustering pr

210 of integrin alpha(v)beta(3) in solution and real-time imaging of the binding process between cRGD an

211 Real-time imaging of the cells infected with the eGFP-ta

212 the tumor-vascular microenvironment enables real-time imaging of the cellular mechanisms of mosaic v

213 fluorescence lifetime imaging (FLIM) enables real-time imaging of the conformational changes of the s

214 subsequent NF-kappaB activation (measured by real-time imaging of the dynamic p65 and IkappaBalpha fl

215 Real-time imaging of the embryonic murine cardiovascular

216 Therefore, real-time imaging of the esophagus may be helpful in red

217 Real-time imaging of the motion in the solvated state us

218 ffers design rules for new protein pores and real-time imaging of the secondary structures of RNA.

219 ection interference microscope to enable the real-time imaging of the solid-electrolyte interphase du

220 ptical coherence tomography (OCT) system for real-time imaging of the tissue in front of the needle t

221 This makes possible high-resolution, real-time imaging of these cells by magnetic resonance i

222 Real-time imaging of these mutants with GFP-labeled chro

223 Real-time imaging of this assembly has the potential to

224 We deployed the DNA-encapsulated QDs for real-time imaging of three different endocytic ligands-f

225 In further support, real-time imaging of tropomyosin-receptor-kinase-A vesic

226 and short acquisition times pave the way for real-time imaging of ultrafast processes or visualizatio

227 utrophil and macrophage function gained from real-time imaging of zebrafish.

228 rated into the microscope to allow for true 'real-time' imaging of instrument-tissue interactions.

229 tainties at the time of treatment, including real-time imaging on the linear accelerator.

230 its from high instrument sensitivity so that real-time imaging or imaging with a limited number of ac

231 plete mapping of live tissues, subsequent to real-time imaging or perturbation.

232 Real-time imaging over long fibre lengths opens alternat

233 ime k-t SENSE imaging compared with standard real-time imaging (P < .05).

234 We developed an in situ and real-time imaging procedure to record the interface evol

235 Real-time imaging provided a more detailed fundamental u

236 an axial resolution better than 50 um, and a real-time imaging rate of 5 frames per second.

237 dynamic elastography of soft tissue at near real-time imaging rates.

238 Real-time imaging results reveal that the probe stains t

239 Quantitative real-time imaging revealed a gradual change in the oxida

240 Real-time imaging revealed an immediate tissue response

241 Real-time imaging revealed that arrest phenotypes differ

242 Further, real-time imaging revealed that loss of Lis1 caused defe

243 Real-time imaging revealed that the virus spread sequent

244 Single-molecule real-time imaging revealed that UV-DDB forms transient c

245 Real-time imaging revealed the surprisingly rapid infilt

246 The real-time imaging reveals a surprisingly fast conversion

247 Monitored by real-time imaging, RvD2-DRV2 interaction significantly e

248 Real-time imaging showed rapid uptake of spores into alv

249 Commercial real-time imaging software was customized to facilitate

250 Here we present a closed-loop real-time imaging strategy that automatically compensate

251 Real-time imaging studies are reshaping immunological pa

252 Additionally, the results of live real-time imaging studies demonstrated that C. neoforman

253 Single-cell, real-time imaging studies on E. coli reveal an autocatal

254 In this paper, we propose a real-time imaging system using flexible MMFs, but which

255 We have devised a noninvasive real-time imaging technique using confocal laser-scannin

256 Functional magnetic resonance imaging, a real-time imaging technique, was used to determine the a

257 g the degradation of apoptotic cells using a real-time imaging technique.

258 Increased use of various online and real-time imaging techniques is an important step toward

259 However, because of the lack of real-time imaging techniques, specific subcellular mecha

260 microglial dynamics recently uncovered using real-time imaging techniques.

261 With the improvement in real-time imaging technologies and tools for direct acce

262 report the use of a newly developed ex vivo real-time imaging technology and immunoassaying to trace

263 In addition, recent advances in real-time imaging technology have begun to measure the r

264 Here, we demonstrate through real-time imaging that individual rat and human pancreat

265 Here we optimize single-cell real-time imaging to delineate the cellular mechanisms f

266 Using real-time imaging to follow the fate of ingested bacteri

267 an approach with RNA interference (RNAi) and real-time imaging to study cyclin contributions to the r

268 We demonstrate through-wall real-time imaging, tracking, and observe second-order im

269 This work demonstrates that real-time imaging under controlled atmosphere is a power

270 re, we summarize quantitative lipidomics and real-time imaging used in PA studies and highlight recen

271 ared to diploid (2n) embryos was revealed by real-time imaging, using a histone H2b:eGFP reporter.

272 Real-time imaging was performed at the center of restora

273 r the intradisulfide modulates cGMP binding, real-time imaging was performed in vascular smooth muscl

274 Real-time imaging was performed with a mobile device to

275 Using the combination of high-resolution and real-time imaging, we demonstrate that these artificial

276 By monitoring individual HSC behaviour using real-time imaging, we found that a portion of the homed

277 Using intersectional genetics and real-time imaging, we show that SCN cells expressing vas

278 Using real-time imaging, we show that Spastin severs microtubu

279 By utilizing molecular analysis and real-time imaging, we show that two progenitor character

280 Real-time imaging will enable efficient process developm

281 ab allows full control of the device and the real-time imaging with a region-of-interest (ROI) method

282 Real-time imaging with a VGAT-pHluorin fusion provides a

283 res the safety and tissue targeting value of real-time imaging with co-infused gadoteridol and putati

284 opaque, stage VI Xenopus oocytes, for which real-time imaging with conventional technologies is chal

285 d invasive human glioma models and employing real-time imaging with correlative neuropathology, we de

286 imaging, interventional imaging prioritizes real-time imaging with lower radiation dose in addition

287 Synchronization of 2D real-time imaging with patient ECG allowed for different

288 Real-time imaging with reporter enzyme fluorescence (REF

289 ercise CMR with non-ECG-gated free breathing real-time imaging, without any additional physiological