ライフサイエンスコーパス: multicolor

1 number of innovative solutions have emerged, multicolor 3D techniques still face significant technica

2 TP-DSO will advance multicolor analysis for many applications.

3 This technique advances multicolor analysis significantly by resolving dyes with

4 The multicolor and multiplexing capabilities of semiconducto

5 LSSmOrange allows numerous multicolor applications using a single-excitation wavele

6 fluorescent protein (mTFP1) for multiphoton, multicolor applications.

7 In addition, a multicolor assay that uses four different fluorescently

8 For the multicolor assay, a desired selection substrate was used

9 This bottom-up method readily affords multicolor-banded crystals in gram quantity by varying t

10 applications in high-resolution bioimaging, multicolor barcoding, and driving multiple important pho

11 nd Mad family proteins in living cells using multicolor BiFC analysis.

12 Multicolor BiFC was used to simultaneously visualize A(2

13 e beta(5) complex formation in vivo, we used multicolor bimolecular fluorescence complementation in h

14 ns of the two iRFP chimeras enables combined multicolor bioluminescence imaging (BLI) and the respect

15 Here, we have developed a new multicolored bioluminescence-based reporter system that

16 s and enable stochastic, intersectional, and multicolor Brainbow labeling.

17 Furthermore, multicolor capabilities are shown with minimal cross-tal

18 Finally, to demonstrate the multicolor capability of the system, 19-wavelength detec

19 Their use in multicolor cellular imaging (see scheme) and in tracking

20 Multicolor characterizations in synovial fluid demonstra

21 Previously, multicolor chromatin labeling has been achieved using or

22 ent signal can be captured and the resultant multicolor chromatograms analyzed.

23 By combining retroviral-based multicolor clonal analysis with live imaging, the result

24 By integrating multiplex targeting, multicolor coding, and multimodal detection, our approac

25 nal (3D) structures, measure interactions by multicolor colocalization, and record dynamic processes

26 lors, but a concatenated tetramer displays a multicolored composite spectrum with little or no spectr

27 Using multicolor confocal intravital microscopy in mouse model

28 olecular interactions from single-channel or multicolor confocal laser-scanning microscopy (CLSM) ima

29 Multicolor confocal microscopy revealed that MM-associat

30 Here, using multicolor confocal microscopy, followed by computationa

31 sonance dispersion as a mechanism to provide multicolor contrast for imaging thin molecular films.

32 Moreover, using a multicolor Cre reporter line, we demonstrate that the re

33 Here, we use a multicolor Cre-dependent marker system to trace clonalit

34 We used multicolor Cre-reporter lineage tracing to show that mos

35 as prompted a flurry of exciting advances in multicolor CRISPR imaging, although color-based multiple

36 We demonstrate spatially resolved multicolor CsPbX3 (X = Cl, Br, I, or alloy of two halide

37 Multicolor CT enabled differentiation of Au-HDL, iodine-

38 acrophages on the aorta sections; hence, the multicolor CT images provided information about the macr

39 The current study utilizes multicolor cytokine flow cytometry to study HIV-specific

40 peripheral blood lymphocytes was assessed by multicolor cytometry.

41 es for on-chip holographic imaging, and (ii) multicolor detection for lensfree fluorescent on-chip mi

42 d with an electrophoretic separation for the multicolor detection of PCR-amplified DNA against a labe

43 has great potential for use in simultaneous multicolor detection schemes.

44 Using a multicolor detection strategy, we performed a spatiotemp

45 es in elongational flow that is coupled to a multicolor detection system capable of single-fluorophor

46 r applications in wavelength-tunable lasers, multicolor detectors, full-spectrum solar cells, LEDs, a

47 An intrinsically soft and stretchable multicolor display and touch interface is reported.

48 sent key building blocks for high-resolution multicolor displays beyond current state-of-the-art tech

49 The method was successfully applied to multicolor DNA detection and the analysis of telomerase

50 ential applications of this platform include multicolor dPCR and massively parallel dPCR for next gen

51 We use multicolor, dual-penetration depth, total internal refle

52 totype is presented where light emission and multicolor electrochromism occur from the same pixel com

53 Multicolor electrophosphorescent organic light-emitting

54 study revealed the staining of the cell and multicolor emission in the presence of H2S.

55 ntration and excitation wavelength dependent multicolor emission properties.

56 We used multicolor evanescent wave fluorescence microscopy imagi

57 nable light emission, signal brightness, and multicolor excitation that are not available from tradit

58 nm) allow their use in otherwise challenging multicolor experiments, e.g., when combining Ca(2+) unca

59 ke Au nanoparticles, they facilitate complex multicolor experiments.

60 Second, APEx two-hybrid coupled with multicolor FACS analysis to account for protein expressi

61 To address this, the current study used multicolor FACS of disaggregated tumor to systematically

62 lection substrate is cleaved are isolated by multicolor FACS with fluorescently labeled antiepitope t

63 Herein, we used various multicolor fate mapping systems to investigate the ontog

64 cardiomyocytes to the atrium in zebrafish by multicolor fate-mapping and we compare our analysis to t

65 Multicolor FISH indicated that the structural chromosoma

66 In this study, use of a detailed multicolor FISH mapping procedure in pathologic specimen

67 ridization (M-FISH), are chromosome-specific multicolor FISH techniques that augment cytogenetic eval

68 omplex were stochastically labeled using the multicolor flip-out technique and a catalog was created

69 Our multicolor flow cytometric analyses of human decidual le

70 n of Tyr was made possible by implementing a multicolor flow cytometric assay for the screening of la

71 Using multicolor flow cytometry and cell sorting, we observed

72 H2 and TH2/TH17 cells were analyzed by using multicolor flow cytometry and confocal immunofluorescenc

73 We used multicolor flow cytometry and IL-7 ELISA to investigate

74 Systematically applying multicolor flow cytometry and immunohistochemistry to tr

75 We used multicolor flow cytometry and intracellular cytokine sta

76 neal dialysis (PD)-associated peritonitis by multicolor flow cytometry and multiplex ELISA, and defin

77 Multicolor flow cytometry and polymerase chain reaction

78 ells in chimpanzees with HCV infection using multicolor flow cytometry and real-time polymerase chain

79 kocyte subpopulations was performed by using multicolor flow cytometry and was combined with stimulat

80 We used multicolor flow cytometry in combination with bioinforma

81 Eosinophils were phenotyped by multicolor flow cytometry in digested lung tissue and br

82 Multicolor flow cytometry of peripheral blood mononuclea

83 d a thorough literature review, we developed multicolor flow cytometry panels to determine the surfac

84 Multicolor flow cytometry quantified the endothelial pro

85 Multicolor flow cytometry revealed that the HLA-C-inhibi

86 u hybridization (Flow-FISH) for IFN-gamma to multicolor flow cytometry that allows for single-cell me

87 We used multicolor flow cytometry to analyze NK cells from the l

88 We used multicolor flow cytometry to evaluate activation (CD38+/

89 We used multicolor flow cytometry to phenotype lymphocyte subpop

90 Multicolor flow cytometry using multiple antibody panels

91 Multicolor flow cytometry was used to analyze the inflam

92 Multicolor flow cytometry was used to determine the freq

93 Multicolor flow cytometry was used to study the DC pheno

94 Here, we combine multicolor flow cytometry with highly efficient 3-dimens

95 Airway inflammation was assessed by using multicolor flow cytometry, and bronchial hyperreactivity

96 ion, quantitative polymerase chain reaction, multicolor flow cytometry, and enzyme-linked immunosorbe

97 Tr1 were phenotyped by multicolor flow cytometry, and suppression of proliferat

98 pheral blood and tonsils were assessed using multicolor flow cytometry, and their developmental pathw

99 Leukocytes were phenotyped using multicolor flow cytometry, and whole-blood transcriptome

100 nding and 14 not responding to ipilimumab by multicolor flow cytometry, antibody-dependent cell-media

101 Multicolor flow cytometry, cell sorting and growth inhib

102 Using a large panel of Abs in multicolor flow cytometry, cell sorting, and RNA sequenc

103 RESEARCH DESIGN AND We applied multicolor flow cytometry, confocal microscopy, and immu

104 Using multicolor flow cytometry, we have uncovered robust hete

105 Using multicolor flow cytometry, we reliably detected IgE-expr

106 METHODS AND TL was measured by multicolor flow cytometry-fluorescent in situ hybridizat

107 f Behcet's disease and sarcoidosis) based on multicolor flow cytometry.

108 lls were analyzed using quantitative PCR and multicolor flow cytometry.

109 s a wide age range (20 to 84 years) by using multicolor flow cytometry.

110 mph node and the site of the infection using multicolor flow cytometry.

111 the beads are pooled and rapidly analyzed by multicolor flow cytometry.

112 (n=10) and PBMC of normal controls (n=10) by multicolor flow cytometry.

113 We used multicolor flow fluorescence in situ hybridization analy

114 Using a multicolor flow-based approach, we identified six distin

115 Multicolor flowcytometric analysis had 82.4% sensitivity

116 Multicolor flowcytometric immunophenotyping was performe

117 of IOL, vitreous analysis was performed via multicolor flowcytometric immunophenotyping.

118 This MultiColor FlpOut (MCFO) approach can be used to reveal

119 Using multicolor fluorescence confocal microscopy, we probed t

120 Multicolor fluorescence correlation spectroscopy has bee

121 Here we establish a new multicolor fluorescence fate mapping system to monitor m

122 Multicolor fluorescence images are acquired and analyzed

123 uminescence imaging (BLI) and the respective multicolor fluorescence imaging (FLI) of the iRFPs.

124 vided the rationale for the development of a multicolor fluorescence in situ hybridization (FISH) pro

125 ttle or no repetitive elements as probes for multicolor fluorescence in situ hybridization (mcFISH),

126 By using a novel, advanced, multicolor fluorescence in situ hybridization approach,

127 lterations in this progression, we used four multicolor fluorescence in situ hybridization probe pane

128 4D atlas for vertebrate early embryos, using multicolor fluorescence in situ hybridization with nucle

129 d distinguished multiple particle types with multicolor fluorescence microscopy and automated image a

130 We used single-molecule millisecond multicolor fluorescence microscopy of live bacteria to r

131 established a method using nanofluidics and multicolor fluorescence microscopy to detect DNA and his

132 detection and characterization of very weak multicolor fluorescence produced by mixtures of various

133 methylated DNA molecules using simultaneous, multicolor fluorescence to identify methyl binding domai

134 Multicolor fluorescence-activated cell sorting could iso

135 We used multicolor fluorescence-activated cell sorting to isolat

136 nsport and its regulation using mutagenesis, multicolor-fluorescence microscopy, and multiplex genome

137 9(+) mouse liver cells at low density with a multicolor fluorescent confetti reporter.

138 Here, we present a new multicolor fluorescent fate mapping system and quantific

139 We used sensitive multicolor fluorescent in situ hybridization to generate

140 Multicolor fluorescent labeling of both intra- and extra

141 plexing approaches for wide-field imaging of multicolor fluorescent objects on a chip.

142 one-step method for the synthesis of bright, multicolor fluorescent sulphur doped carbon dots (CNDs)

143 gy to produce pH-tunable, highly activatable multicolored fluorescent nanoparticles using commonly av

144 While numerous multicolored fluorescent protein (FP) probes have reveal

145 We hypothesize that multicolored fluorescent proteins evolved as part of a m

146 Using multicolored fluorescent reporter lines, we track and pu

147 tectability limit for reaction products with multicolor fluorophores.

148 Hybridization assays in the multicolor format provided a limit of detection of 90 fm

149 scope platform, OMX, that enables subsecond, multicolor four-dimensional data acquisition and also pr

150 nometer lateral resolution for more than 100 multicolor frames, and nonlinear SIM with patterned acti

151 demonstrate that Cal-590 is also suited for multicolor functional imaging experiments in combination

152 Cal-590 can be readily used for simultaneous multicolor functional imaging experiments.

153 usen as visualized by cSLO infrared (IR) and MultiColor (Heidelberg Engineering, Heidelberg, Germany)

154 Multicolor, high-resolution microscopy permits detailed

155 This multiangle and multicolor illumination scheme permits us to dynamically

156 icrom, sufficient for obtaining quantitative multicolor images from >30,000 array elements in an 18 m

157 eously by eye under the microscope, yielding multicolor images of multiple cellular antigens in real

158 ence microscopy, it is inherently capable of multicolor imaging and optical sectioning and, with suff

159 ly higher photostability allowing its use in multicolor imaging applications to track dynamics of mul

160 Furthermore, both 3D and multicolor imaging are readily achievable.

161 Using simultaneous multicolor imaging at individual synapses, we could show

162 Multicolor imaging based on genetically encoded fluoresc

163 demonstrate the utility of these reagents in multicolor imaging experiments by using one of the new H

164 onsistently on near-infrared reflectance and MultiColor imaging in all 36 eyes at every imaging encou

165 rabow (Zebrafish Brainbow) tools for in vivo multicolor imaging in zebrafish.

166 Using this approach, we demonstrate multicolor imaging of DNA model samples and mammalian ce

167 n Danio rerio larvae and spatially isotropic multicolor imaging of fast cellular dynamics across gast

168 uences they target and allows for single and multicolor imaging of regions ranging from tens of kilob

169 ational palette presented here thus opens up multicolor imaging of small biomolecules, enlightening a

170 the macula on near-infrared reflectance and MultiColor imaging that occurs predominantly in pseudoph

171 S-mKates and blue-green fluorophores enables multicolor imaging using a single laser.

172 ght-sheet along the sample surface, enabling multicolor imaging with high spatiotemporal resolution.

173 and the previously engineered iRFP713 allow multicolor imaging with spectral unmixing in living mice

174 uorescence (FAF), near-infrared reflectance, MultiColor imaging, and spectral-domain optical coherenc

175 ntensiometric measurements, compatibility in multicolor imaging, large dynamic ranges, and relatively

176 ective spot on near-infrared reflectance and MultiColor imaging, located at the macula, nasal or supe

177 into six different energy bins was used for multicolor imaging.

178 d temporal resolution and compatibility with multicolor imaging.

179 es, and is sufficiently red-shifted to allow multicolor imaging.

180 aser ophthalmoscope infrared reflectance and MultiColor imaging.

181 reasing the imaging field of view, and using multicolor imaging.

182 on a paper-based platform is presented using multicolor immobilized quantum dots (QDs) as donors in f

183 For the development of the multicolor immunochromatographic test, we used antibodie

184 l cells in prenatal human skin in situ using multicolor immunofluorescence and analyzed angiogenic mo

185 Confocal multicolor immunofluorescence imaging revealed a nonunif

186 ere phenotypically characterized by means of multicolor immunofluorescence labeling.

187 We have successfully mapped by multicolor immunofluorescence the localization pattern o

188 Furthermore through multicolor immunofluorescence, we identify chCD83(+) pop

189 issue from control subjects were examined by multicolor immunofluorescence.

190 ed controls were analyzed using simultaneous multicolor immunofluorescence.

191 Multicolor immunohistochemistry identified cells coexpre

192 he perinodular K19 epithelial loss; however, multicolor immunolabeling for K19, vimentin, E-Cadherin,

193 Using multicolor in vivo confocal microscopy, we found that Co

194 nine HIV dually infected patients by using a multicolor intracellular cytokine staining assay.

195 Multicolor ISM was shown on cytoskeletal-associated stru

196 ce immunostaining include compatibility with multicolor labeling and confocal or multiphoton imaging.

197 ed excitation and emission are desirable for multicolor labeling and live-animal imaging.

198 itates robust cotransduction and stochastic, multicolor labeling for individual cell morphology studi

199 based fluorescence labeling strategy for the multicolor labeling of distinct subcellular compartments

200 ferently colored dCas9/sgRNA complexes allow multicolor labeling of target loci in cells.

201 In this article, we quantitatively establish multicolor labeling strategies for UTP-enriched transcri

202 In the transgenic multicolor labeling strategy called 'Brainbow', Cre-loxP

203 We describe a whole-capillary, multicolor laser-induced fluorescence scanner for microf

204 formation could promote applications such as multicolor lasers, broadband memories, and multiwaveleng

205 Here, we constructed a multicolor lentiviral TALE-Kruppel-associated box (KRAB)

206 ted optical waveguide mixer that can deliver multicolor light at a common waveguide port to achieve m

207 Here we introduce a novel multicolor light sheet fluorescence microscopy (LSFM) ap

208 es in signal brightness, photostability, and multicolor-light emission.

209 Using multicolor lineage labeling, we demonstrate that VSMCs i

210 Here, we performed clonal multicolor lineage tracing of skeletal muscle stem cells

211 In this study, we used multicolor lineage tracing to demonstrate that polyclona

212 e first one based on statistical analysis of multicolor lineage tracing, allowing the definition of m

213 Using multicolor lineage-tracing and organoid-formation assays

214 The multicolor live cell imaging experiments in HeLa cells s

215 ation precision, ultrahigh-labeling density, multicolor localization microscopy in samples up to 20 m

216 Herein we describe a multicolor, long-term (>24 h) imaging strategy for measu

217 Such systems with convertible multicolor luminescence might exhibit application potent

218 challenge of achieving the photoswitching of multicolor luminescence on unimolecular platforms, we he

219 ein, we report a method of in vivo real-time multicolor lymphatic imaging using cadmium-selenium quan

220 vivo or in situ under surgery with real-time multicolor lymphatic imaging.

221 This noninvasive and biocompatible multicolor method of optical lymphangiography may elucid

222 raffin-embedded (FFPE) tissues, we developed multicolor miRNA FISH.

223 are readily identified and reliably sized in multicolor mixtures of large and small beads.

224 light at a common waveguide port to achieve multicolor modulation of the same neuronal population in

225 less operation of independently addressable, multicolor mu-ILEDs with fully implantable, miniaturized

226 ic, green-fluorescent sensor ZP1 can perform multicolor/multianalyte microscopic imaging.

227 of individual cultured mammalian cells using multicolor multicycle immunofluorescence with quantum do

228 Incubation of a mixture of multicolored nanoparticles with human H2009 lung cancer

229 e shifts (<40 nm) and established a panel of multicolored nanoparticles with wide emission range (500

230 We developed a multicolor neuron labeling technique in Drosophila melan

231 e drainage patterns of the lymphatic system, multicolor optical probes must be developed, which can b

232 R1, with a red-shifted absorption suited for multicolor optogenetic experiments in combination with b

233 be used to encrypt and selectively disclose multicolor patterns for anticounterfeiting applications.

234 This multicolored, pH-tunable nanoplatform offers exciting op

235 reversible transition was observed between a multicolor (phase-separated) and a single-color (mixed)

236 g of a carbon fiber-ZnO hybrid nanowire (NW) multicolor photodetector is driven by a microbial fuel c

237 Multicolor PLEDs were also demonstrated by taking advant

238 By developing multicolor probes, we showed that most polysomes act ind

239 electroactive and electrochromic materials, multicolored proof-of-concept electrochomic devices were

240 In particular, the use of multicolor QD probes in immunohistochemistry is consider

241 dy conjugation, tissue specimen preparation, multicolor QD staining, image processing and biomarker q

242 eneity and rarity problem, we have developed multicolor QD-antibody conjugates to simultaneously dete

243 These properties of QDs allow multicolor QDs to be excited from one source by common f

244 design in terms of relative concentration of multicolor QDs.

245 opy images of the beads demonstrate that the multicolored QDs are pushed together into inclusions wit

246 Candida QuickFISH BC, a multicolor, qualitative nucleic acid hybridization assay

247 Here, we combine a multicolor quantum dot (QD)-based immunofluorescence ass

248 Multicolor quantum dot-encoded polymeric microspheres ar

249 mRNAs and their corresponding proteins with multicolor quantum dots.

250 G-band peaks and can be used for multiplexed multicolor Raman imaging of biological systems.

251 x (anti-Her1), and RGD peptide, allowing for multicolor Raman imaging of cells in a multiplexed manne

252 ar single-walled carbon nanotubes (SWNTs) as multicolor Raman labels for highly sensitive, multiplexe

253 applications to be run and established that multicolor reagent mixtures containing V450-antibody con

254 , magnetic enrichment, signal amplification, multicolor recognition, and feedback control, could be u

255 e achieve pixels with polarization dependent multicolor reflection on mirror-like surfaces.

256 Multicolor reporter analysis revealed that Nkx2-5-null c

257 , the combination of inducible recombinases, multicolor reporter constructs, and live-cell imaging ha

258 Here, we use clonal cell labeling with multicolor reporters to characterize individual mesenchy

259 of reliable clinical laboratory- compatible multicolor RNA FISH methodology for molecular diagnostic

260 Here we report the identification of a multicolor set of water-soluble ODF dyes that display em

261 e describe a rapid, automated, and sensitive multicolor single molecule detection apparatus and a nov

262 Here we developed a multicolor single-molecule fluorescence approach to simu

263 stablished an experimental approach based on multicolor single-molecule fluorescent in situ hybridiza

264 purified fascin bound directly to Daam1, and multicolor single-molecule TIRF imaging revealed that fa

265 uorescence activated cell sorting (FACS) for multicolor sorting to simultaneously screen for affinity

266 rce excitation and simultaneous detection of multicolor species without complicating experimental set

267 Through the use of multicolor stimulated emission depletion microscopy, we

268 These tools enable efficient multicolor stochastic labeling of neurons at both low an

269 witchable fluorescent probes and demonstrate multicolor stochastic optical reconstruction microscopy

270 levels similar to that obtained with complex multicolor strategies.

271 d and demonstrated the utility of proExM for multicolor super-resolution ( approximately 70 nm) imagi

272 Multicolor super-resolution imaging, however, remains a

273 use of multifocus microscopy for volumetric multicolor superresolution imaging.

274 ssue at single-cell resolution, we created a multicolor system, skinbow, that barcodes the superficia

275 Together, our results suggest that this multicolor TALE-KRAB vector platform is a promising and

276 We showed that this multicolor TALE-KRAB vector system when combined togethe

277 Here we demonstrated multicolor three-dimensional (3D) stochastic optical rec

278 Multicolor three-dimensional (3D) superresolution techni

279 methods have been extended to live cells and multicolor, three-dimensional imaging, thereby providing

280 Using multicolor, three-dimensional stochastic optical reconst

281 New opportunities keep emerging with the multicolor, three-dimensional, and live imaging function

282 first example of a one-donor/three-acceptor multicolor time-resolved fluorescence energy transfer (T

283 When used for the automated analysis of multicolor, tissue-microarray images, SFT correctly foun

284 Here, using multicolor total internal reflection fluorescence micros

285 Here, we used multicolor total internal reflection fluorescence micros

286 We have used multicolor total internal reflection fluorescence micros

287 Finally, multicolor transcriptional and posttranslational modific

288 ng and transduction of chemical signals with multicolor transmission of alphanumeric information.

289 We directly observed multicolored tumor cell clusters across major stages of

290 nal microrods as the template enables facile multicolor tuning in a single crystal, which is inaccess

291 Developing multicolor upconversion nanoparticles (UCNPs) with the c

292 Here we report the design of multicolor versions of CRISPR using catalytically inacti

293 r red fluorescent protein variants, allowing multicolor visualization of cellular markers and secrete

294 s coding for different color reporters allow multicolor visualization of neurons wherever applied.

295 ains, smFP probes allowed robust, orthogonal multicolor visualization of proteins, cell populations a

296 Here, we developed a method of two-photon multicolor vital imaging to observe competitive eliminat

297 roscopy (SIM or3D-SIM, respectively) enables multicolor volumetric imaging of fixed and live specimen

298 We applied this system to multicolor volumetric imaging of processes sensitive to

299 the super-resolution technique of choice for multicolor volumetric imaging.

300 We demonstrate the power of this multicolor 'Wave' marker set for rapid, combinatorial an