ライフサイエンスコーパス: bioimaging

1 (double cholesteryl) using fluorescent live bioimaging.

2 ensors, and (4) metal-containing polymers in bioimaging.

3 elopment of fluorescence probes suitable for bioimaging.

4 n used as biocompatible fluorophores in cell bioimaging.

5 ort outlook on future directions of QD-based bioimaging.

6 -like to spherical), and also tumor-targeted bioimaging.

7 se in optics, optoelectronics, catalysis, or bioimaging.

8 ific features of nanomaterials often used in bioimaging.

9 d designated the suitability for subcellular bioimaging.

10 predetermined composition and morphology for bioimaging.

11 from quantum information to neuroscience and bioimaging.

12 ing NIR fluorescent tags for applications in bioimaging.

13 and enhance the brightness of QD probes for bioimaging.

14 Hcy but also can penetrate cells for Cys/Hcy bioimaging.

15 e bullets for in vitro and in vivo molecular bioimaging.

16 ications, e.g. in quantum dot research or in bioimaging.

17 optical amplifiers, solar concentrators, and bioimaging.

18 emically specific sensing, and near-infrared bioimaging.

19 croscopy, quantum information processing and bioimaging.

20 can play in areas such as energy storage and bioimaging.

21 ld impact tissue engineering, drug delivery, bioimaging.

22 problems in applications from solar cells to bioimaging.

23 y, have exhibited great potential in PDT and bioimaging.

24 e and wash-free target sensing and live-cell bioimaging.

25 d NPs stain cells and are thus promising for bioimaging.

26 g viscosity variations are valuable tools in bioimaging.

27 it inks, night-vision readable displays, and bioimaging.

28 ive measurement techniques from astronomy to bioimaging.

29 ing it a potentially effective new probe for bioimaging.

30 molecules that serve as fluorescent dyes for bioimaging.

31 airway physiology, airway inflammometry, and bioimaging.

32 valed contrast agents for NIR-II preclinical bioimaging.

33 ds of drug delivery, tissue engineering, and bioimaging.

34 lds in the development of new NIR probes for bioimaging.

35 nce properties (M = Yb and Eu) essential for bioimaging.

36 ), photovoltaic cells, chemical sensors, and bioimaging.

37 as revolutionized biology, due to its use in bioimaging.

38 e, this probe can be successfully applied in bioimaging.

39 s have been widely applied in biosensing and bioimaging.

40 lular dynamics and, hence, open a new era of bioimaging.

41 therapy, drug/gene delivery, biosensing, and bioimaging.

42 Here, we introduce near-zero photon bioimaging, a method that operates at kHz rates and 10,0

43 o promote the clinical translation of NIR-II bioimaging, advancements in the high-performance small m

44 ent proteins (RFPs) are highly desirable for bioimaging advances.

45 Fluorescence bioimaging affords a vital tool for both researchers and

46 Mice subjected to bioimaging after neonatal intracranial or intravascular

47 rent functional moieties including aptamers, bioimaging agents and drug-loading sites could be easily

48 s offer diverse opportunities for developing bioimaging agents and fluorescence probes.

49 The development of probes (also called bioimaging agents and intracellular sensors) to achieve

50 ments, optimal linkers, drug combinations or bioimaging agents.

51 er remarkable opportunities in the design of bioimaging agents: this review presents an accessible di

52 Bioimaging analysis showed that the mutant aberrantly ac

53 proteins (FPs) have played a pivotal role in bioimaging and advancing biomedicine.

54 g P-dots will be very useful in a variety of bioimaging and analytical applications.

55 robes would provide new avenues to designing bioimaging and biological diagnosis.

56 ospect of this dye's use for amyloid fibrils bioimaging and biosensing in vivo.

57 Continued development of SERS 3D bioimaging and biosensing systems, techniques, and analy

58 le photoluminescence for use in fluorescence bioimaging and biosensing, a high loading capacity of ar

59 entirely new generation of useful probes for bioimaging and biosensing.

60 ions not only in optoelectronics but also in bioimaging and biosensing.

61 operties in biological applications, such as bioimaging and biosensing.

62 behavior of Au25 (SG)18 for applications in bioimaging and biotherapy.

63 ising candidates for various applications in bioimaging and catalysis.

64 many areas from high-power fiber lasers, to bioimaging and chemical sensing, and to intriguing physi

65 lently used in diverse research areas (e.g., bioimaging and chemosensing) as they exhibit promising f

66 est in encapsulating bioactive molecules for bioimaging and controlled delivery applications.

67 Today, this includes applications in bioimaging and diagnosis, photodynamic therapy regimes,

68 onjugates, making them potentially useful in bioimaging and diagnostic applications.

69 organic light emitting diodes, solar cells, bioimaging and diagnostics.

70 sfection agents, and their use as agents for bioimaging and DNA delivery are also demonstrated.

71 mise of NCPDs in bio-related fields, such as bioimaging and drug delivery, are systematically discuss

72 designing materials for applications such as bioimaging and drug delivery, as well as for assessing e

73 ions, including biosensing, cell modulation, bioimaging and drug delivery.

74 luorophores HLAnP (n = 1-4) for simultaneous bioimaging and drug delivery.

75 ions of InAs QDs, with a particular focus on bioimaging and field effect transistors.

76 vide valuable benefits as optical probes for bioimaging and Forster resonant energy transfer (FRET) d

77 Continued advances in bioimaging and functional genomics will be important for

78 ntial progress in combining high-dimensional bioimaging and genomic data, methods for imaging genomic

79 ly encodable probes that have revolutionized bioimaging and health fields with vivid images and an ev

80 BODIPYs for various applications, including bioimaging and in dye-sensitized solar cells.

81 tive GNC-F2 will find use both as a tool for bioimaging and in the high-throughput selection and engi

82 cid surface ligands are highly effective for bioimaging and in vivo tumor targeting.

83 Based on quantitative bioimaging and molecular markers for genetic and signali

84 advances in gold nanostructure based in vivo bioimaging and photothermal therapy and their loading ca

85 acilitating their biomedical applications in bioimaging and photothermal therapy of cancer.

86 (quantum dots, QDs) have great potential in bioimaging and sensing applications due to their excelle

87 use of semiconductor quantum dots (QDs) for bioimaging and sensing has progressively matured over th

88 om the perspective of enhanced near-infrared bioimaging and sensing in water, the results show how th

89 re for a dynamic AIE molecular system in the bioimaging and sensing study.

90 The combined use of elemental bioimaging and speciation analysis is presented as a nov

91 emical proteomic strategies for simultaneous bioimaging and target identification of noncovalent bioa

92 e summarized the development of oHC PPGs for bioimaging and the controlled release of therapeutics, b

93 ver, as biologists are adopting quantitative bioimaging and these experiments become more complex, re

94 al applications in tribology, drug delivery, bioimaging and tissue engineering, and also as protein m

95 Bioimaging and xylem sap analyses suggest that the reduc

96 e variations, near-infrared fluorophores for bioimaging, and beta-cyclodextrins for potential drug de

97 cability of this approach for drug delivery, bioimaging, and cell targeting was also demonstrated.

98 er a novel molecular approach to biosensing, bioimaging, and disease therapy.

99 ation (LA) ICP-MS for quantitative elemental bioimaging, and hydrophilic interaction liquid chromatog

100 estern analysis, high-resolution single-cell bioimaging, and in situ confocal microscopy of seminifer

101 en oxide nanoparticles for light harvesting, bioimaging, and sensing.

102 s biosensing, disease diagnosis and therapy, bioimaging, and so on.

103 ing popular for applications in diagnostics, bioimaging, and therapeutics.

104 is, structure, photophysical properties, and bioimaging application of a novel 2,1,3-benzothiadiazole

105 s, and high photostability reveal promise in bioimaging application.

106 ential in enhancing actin polymerization, in bioimaging applications and as a novel avenue in cancer

107 ver, they have not been extensively used for bioimaging applications due to the lack of structural in

108 geted near-infrared fluorophores for various bioimaging applications is described.

109 Finally, the potential bioimaging applications of COUPY-octreotide conjugates w

110 s with suitable photophysical properties for bioimaging applications, including emission in the far-r

111 feasibility for chemical species sensing and bioimaging applications.

112 derivative to be used as a stable probe for bioimaging applications.

113 sed of UCNPs and plasmonic nanostructures in bioimaging applications.

114 rating their utility for use in cellular and bioimaging applications.

115 re widespread use of SERS for biosensing and bioimaging applications.

116 applied in designing ratiometric probes for bioimaging applications.

117 vorable for designing ratiometric probes for bioimaging applications.

118 favorable for ratiometric Hg(2+) sensing and bioimaging applications.

119 e new opportunities for photonic devices and bioimaging applications.

120 ique properties as fluorophores with uses in bioimaging applications.

121 ivatives for potential cellular delivery and bioimaging applications.

122 zer and emitter for photodynamic therapy and bioimaging applications.

123 facilitates the use of deconvolution in many bioimaging applications.

124 d are employed in various optoelectronic and bioimaging applications.

125 ing, controlled assembly, and biosensing and bioimaging applications.

126 EB-NS have the potential for a wide range of bioimaging applications.

127 Here, we present a multimodal bioimaging approach combining micro X-ray fluorescence (

128 The bioimaging approach provides a useful means to accuratel

129 We describe a novel bioimaging approach with implications for the evaluation

130 Using a bioimaging approach, we previously demonstrated that a d

131 Here the bioimaging approaches Raster Image Correlation Spectrosc

132 The examples of 2PA applications in bioimaging are also presented, with a comment on future

133 applications of Si QDs and FNDs to long-term bioimaging are discussed in this review comparing the to

134 imaging is a powerful analytical approach in bioimaging, as it offers complementary information on th

135 We here present a method for multielement bioimaging at the cellular level in roots of the genetic

136 otechnology has led to broad applications in bioimaging, basic biological mechanism studies, disease

137 ontainers for applications in drug delivery, bioimaging, biocatalysis, and cell mimicry.

138 Bioimaging, biodistribution, activated neutrophil inhibi

139 ng promise for applications in areas such as bioimaging, biomedicine, photovoltaics and optoelectroni

140 Progress toward the application of GQDs in bioimaging, biosensing, and therapy is reviewed, along w

141 tensive applications of FNA-nanomaterials in bioimaging, biosensing, biomedicine, and other important

142 tensive applications of FNA nanomaterials in bioimaging, biosensing, biomedicine, and other important

143 ations in tissue engineering, drug delivery, bioimaging, biosensors, catalysis and bioelectronics.

144 ogically validated software (vascuCAP Elucid Bioimaging, Boston, MA) before and after biologic therap

145 otophysical properties are highly useful for bioimaging, but such dyes are still rare.

146 nsing and imaging, but their versatility for bioimaging can be limited by undesirable photon interact

147 n exciting opportunities in deep-penetration bioimaging, chemically specific sensing, and quantum tec

148 is and as an effort to aid that of the wider bioimaging community, we present, explain and discuss a

149 High-resolution 3D bioimaging confirmed differential internalization: PS-CO

150 Histologic examination results and elemental bioimaging confirmed labeled cells as source of MR signa

151 as well as improved fluorescent labeling for bioimaging could be envisioned.

152 model demonstrates the feasibility of using bioimaging coupled with Cre/loxP conditional knock-in to

153 initial development BioImage Archive accepts bioimaging data associated with publications, in any for

154 Bioimaging data have significant potential for reuse, bu

155 Quantitative analysis of bioimaging data is often skewed by both shading in space

156 rful tools to analyse, restore and transform bioimaging data, increasingly used in life sciences rese

157 able, accessible, interoperable and reusable bioimaging data.

158 Ex vivo bioimaging demonstrated a high accumulation of phosphati

159 The applications of SNCs in bioimaging/diagnosis and drug delivery/therapy and the s

160 est for a variety of applications, including bioimaging, drug delivery and photovoltaics.

161 development of DNA nanomachines, biosensing/bioimaging, drug delivery, etc.

162 l applications of YSNs including biosensing, bioimaging, drug/gene delivery, and cancer therapy are d

163 range (1.5-1.7 mum) show great potential for bioimaging due to their large tissue penetration.

164 Many reagents for bioimaging employ a fluorescence readout, but the relati

165 Elemental bioimaging enabled visualization of gadolinium depositio

166 th a precisely defined size range applied to bioimaging, enabling multiplexed labeling by allowing re

167 is an essential parameter for high-contrast bioimaging, especially for overcoming auto fluorescent b

168 While a number of biochemical and bioimaging experiments suggest decondensed chromatin str

169 the commercial dye was used to carry out the bioimaging experiments.

170 nhance the utility of conjugated polymers in bioimaging field.

171 ultrasensitive biomarker detection, enhanced bioimaging for disease diagnosis, targeted drug and gene

172 Collectively, our data support the use of bioimaging for lethality prediction following vaccinia v

173 P probes into the cytoplasm to realize their bioimaging functions.

174 New developments in bioimaging have vastly enhanced our ability to study the

175 in flatworm parasites since those driven by bioimaging, immunocytochemistry, and neuropeptide bioche

176 We have evaluated luciferase bioimaging in conscious, unrestrained mice after neonata

177 aching, is a significant problem in extended bioimaging in life science.

178 Luciferase bioimaging in living animals is increasingly being appli

179 arcodes have been implemented favourably for bioimaging, in addition to their security and multiplex

180 a new community effort that combines modern bioimaging informatics, recent leaps in labeling and mic

181 face, and should prove useful for multimodal bioimaging, interfacing with biological systems, reducin

182 Fluorescence bioimaging is a powerful, versatile, method for investig

183 Being poorly invasive, fluorescence bioimaging is suitable for long-term observation of biol

184 The new challenge in bioimaging is to design chemical probes for three-dimens

185 asma-mass spectrometry (LA-ICP-MS) elemental bioimaging is usually constrained by the diameter of the

186 y (bio)molecular detection, while in optical bioimaging it ensures high spatial and temporal resoluti

187 ation, with applications in optical cooling, bioimaging, lasing, and quantum optics.

188 ntial applications in various fields such as bioimaging, light-emitting devices, and photocatalysis.

189 ecies, and reactive nitrogen species) and in bioimaging (lymph nodes, vasculature, tumors, and brain

190 in-situ generation of CuNCs for sensing and bioimaging may be an entry point for the in-depth studie

191 s issue of Neuron, Shafer et al. use a novel bioimaging methodology to demonstrate that PDF elevates

192 t ligation (pBDL), with a novel longitudinal bioimaging methodology to quantify transcription factor

193 Advanced bioimaging methods and genetic show that Al(3+) misfolds

194 Contemporary bioimaging methods provide exceptional resolution genera

195 background autofluorescence in steady-state bioimaging microscopy.

196 ynthesis and fabrication, stem cell biology, bioimaging, microsurgery procedures, and microscale tech

197 nary potential as contrast agents in various bioimaging modalities, near-IR photothermal therapy, and

198 ) complexes, with promising implications for bioimaging, molecular probes, and circularly polarized o

199 latforms for applications in high-resolution bioimaging, multicolor barcoding, and driving multiple i

200 rs, elemental uptake and accumulation, plant bioimaging, nanomaterials in the environment, and exposu

201 the fields of chemical sensing, biosensing, bioimaging, nanomedicine, photocatalysis and electrocata

202 reat promise for single-particle analysis in bioimaging, nanophotonics, and nanocatalysis.

203 r applications in biodetection and molecular bioimaging, near-infrared (NIR) fluorescent dyes are bei

204 oncomitant type 2 diabetes, as well as novel bioimaging NO-based diagnostic tools.

205 the newly disclosed applications in sensing, bioimaging, novel solar energy exploitation including ph

206 Advances in bioimaging now permit in situ proteomic characterization

207 Moreover, the two-photon bioimaging of 3D human forebrain organoids confirms the

208 its potential application in high resolution bioimaging of bacterial nucleoid segregation.

209 tined for in vitro and in vivo targeting and bioimaging of cancer biomarkers, an emerging and fast-gr

210 delivery of drugs and antigens, and optical bioimaging of cells and tissues with state-of-the-art na

211 gies in zebrafish allows for interconnecting bioimaging of disease mechanisms with behavioral analysi

212 ularly imprinted polymer (MIP) particles for bioimaging of fixed and living human keratinocytes, to l

213 The C-dots were also used for bioimaging of fungus and the results show they are also

214 Real-time bioimaging of infectious disease processes may aid count

215 ays, gene expression assays, drug screening, bioimaging of live organisms, cancer studies, the invest

216 hus, whereas apomaghemites are active for MR bioimaging of liver for 45 days, standard SPIO is not ef

217 a unique mouse model that allows noninvasive bioimaging of mdr1 gene expression in vivo and in real t

218 useful ion yields are high enough to enable bioimaging of peptides and lipids in biological samples

219 sitivity to important lipid molecules in the bioimaging of rat brain.

220 Multiplexed immunofluorescence bioimaging of single-cells and their spatial organizatio

221 e and in in vivo applications, e.g., for the bioimaging of small animal models.

222 -ICP-MS) was utilized for spatially resolved bioimaging of the distribution of silver and gold nanopa

223 at can be used in a bidirectional manner for bioimaging of transgene-expressing PCs in zebrafish (bot

224 has diverse potential applications including bioimaging, optical sensors, and photovoltaics.

225 lid-state materials are highly desirable for bioimaging, optoelectronic applications, and energy harv

226 s timely topics such as mechanochemistry for bioimaging or chalcogen bonds for catalysis and solar ce

227 ed on luminescent metallomesogens for use in bioimaging or drug delivery.

228 lopment of site-directed chemical agents for bioimaging or therapeutic applications.

229 ond optical microscopy, the near-zero photon bioimaging paradigm can be applied in remote sensing, co

230 aggregates exhibits excellent tumor-targeted bioimaging performance after intravenously injection int

231 distribution properties that greatly enhance bioimaging performance.

232 advancement of various technologies such as bioimaging, photonics, and OLEDs.

233 in the nervous system is a key step in many bioimaging pipelines involving classification and labeli

234 Leveraging high-content bioimaging pipelines, we demonstrate a relationship betw

235 using MGNs may be a promising diagnostic and bioimaging platform for very harsh conditions.

236 data extraction is integrated into a larger bioimaging platform, Icy, to increase the visibility and

237 ar shell makes ultrasensitive biosensing and bioimaging possible.

238 al fluorescent protein (FP)-based methods in bioimaging, primarily due to their favorable photophysic

239 stly, experiments involving visualization of bioimaging probe distribution in the lungs after local a

240 design an efficient ratiometric fluorescent bioimaging probe for metal ions.

241 use of [a]phenanthrene-fused BODIPYs as NIR bioimaging probes.

242 Single-cell bioimaging profiles many disease-associated protein biom

243 pt will be there to highlight several recent bioimaging reagents and studies that have provided insig

244 use in drug/gene delivery, phototherapy, and bioimaging, recent studies have revealed that FGNs can s

245 between spatial metabolomics and the broader bioimaging research community, promoting open, accessibl

246 fluorescent probes for in vitro and in vivo bioimaging research.

247 ion, which is consistent with our multimodal bioimaging results for primary human keratinocytes, huma

248 ganic pigments and metals were localized via bioimaging, revealing distribution patterns that may hel

249 e of multifunctional applications, including bioimaging, security protection, optical display, optoel

250 Cyanine dyes are widely used in bioimaging, sensing, optoelectronic, and medicinal appli

251 potential important applications such as in bioimaging, sensing, or optoelectronics.

252 Bioimaging software developed in a research setting ofte

253 Previously, each open-source bioimaging software package had its own distinct forum o

254 ic characteristics of usability toward which bioimaging software projects should aim.

255 age of their luminescent properties, such as bioimaging, solid-state lighting, and luminescent solar

256 in tumor targeting and the effectiveness of bioimaging, specifically for theranostics, in tracking d

257 In addition, bioimaging studies against Bacillus subtilis through con

258 he free drug, permitting use of fluorescence bioimaging studies.

259 rst enzyme reporting two-photon fluorescence bioimaging system which was designed exclusively from a

260 re highly desired for many advanced forms of bioimaging techniques and applications.

261 (Cy7) are fluorophores essential for modern bioimaging techniques and chemistry.

262 New bioimaging techniques capable of visualising the co-loca

263 New bioimaging techniques have recently been proposed to vis

264 ompatible Pdots will be useful in developing bioimaging techniques in the future.

265 Pulsed lasers are key elements in nonlinear bioimaging techniques such as two-photon fluorescence ex

266 cision stable isotope measurements and novel bioimaging techniques to characterize parallel water-bor

267 We used bioimaging techniques to document ingestion, egestion, a

268 An electron-microscopy-based bioimaging technology capable of localizing individual p

269 nce lifetime imaging is an important tool in bioimaging that allows one to detect subtle changes in c

270 s of two complementary methods for elemental bioimaging, the nondestructive micro X-ray fluorescence

271 regarded as promising agents for biosensors, bioimaging, therapeutic delivery, and theranostics, as w

272 pace-based imaging (through the atmosphere), bioimaging (through skin and human tissue), and fiber-ba

273 ing longitudinal TFAR profiling by continued bioimaging throughout the lives of the animals and follo

274 reasons, FbFPs hold strong promise to extend bioimaging to clinically and industrially significant sy

275 We modeled a SCA13 zebrafish accessible for bioimaging to investigate disease progression, revealing

276 Finally, we use somatotransgenic bioimaging to longitudinally quantify LPS- and ActivinA-

277 that has applications in fields ranging from bioimaging to microfabrication.

278 We applied conscious bioimaging to the assessment of NFkappaB and STAT3 trans

279 in a variety of biomedical applications from bioimaging, to controlled drug delivery and cellular-dir

280 ted tunable spectral reach for spectroscopy, bioimaging, tomography and metrology.

281 Cryo-Electron Tomography (cryo-ET) is a 3D bioimaging tool that visualizes the structural and spati

282 Chemical probes are key components of the bioimaging toolbox, as they label biomolecules in cells

283 und applications in photodynamic therapy and bioimaging, two-photon absorption (TPA), the simultaneou

284 nities in spectroscopy of nanosized objects, bioimaging, ultrasensitive sensing, molecular computers,

285 Bioimaging under such conditions is suboptimal, as it ei

286 a melanogaster was investigated by elemental bioimaging using laser ablation-inductively coupled plas

287 In vivo bioimaging using shortwave infrared (SWIR) molecular dye

288 Three-dimensional (3D) bioimaging, visualization and data analysis are in stron

289 Conscious bioimaging was applied to a neonatal mouse model of cere

290 Whole-body bioimaging was employed to study the effects of passive

291 Whole-body bioimaging was used to study dissemination of vaccinia v

292 f UV irradiation with visible light benefits bioimaging, while the spectral benchmark of a trapped ch

293 mmunotherapy in mice using in vivo apoptosis bioimaging with a caspase-3 sensor.

294 shown tremendous promise for applications in bioimaging with an ultra-high signal-to-background ratio

295 volving field that combines state-of-the-art bioimaging with genomic information to resolve phenotypi

296 tional fluorescence microscopy, allowing for bioimaging with nanometer resolution.

297 Recent advances in fluorescence bioimaging with single-molecule sensitivity have relied

298 Based on the results herein, bioimaging with WLI was demonstrated as a novel rapid ba

299 highly attractive luminescent biomarkers for bioimaging without autofluorescence and concern of overh

300 bridges optical biosensing and intracellular bioimaging without requiring a labeling process or coupl