ライフサイエンスコーパス: 3D imaging

1 E2-dependant engulfment of LCs by real-time 3D imaging.

2 priori knowledge of the target location for 3D imaging.

3 o the artifact issues encountered with gated 3D imaging.

4 ipped with retractable septa to allow 2D and 3D imaging.

5 ological investigation of organoids based on 3D imaging.

6 s, and machine learning for new frontiers in 3D imaging.

7 s the imaging technique for performing rapid 3D imaging.

8 -ray scattering and cryo-electron microscopy 3D imaging.

9 nd provide spectral information for in-depth 3D imaging.

10 ceptible to fetal movement, particularly for 3D imaging.

11 toms and an ex vivo chicken liver through 2D/3D imaging.

12 y in situ, combined with tissue clearing and 3D imaging.

13 required in conjunction with high resolution 3D-imaging.

14 ination to enable dynamic three-dimensional (3D) imaging.

15 ns and nucleic acids, and three-dimensional (3D) imaging.

16 ugh the gold standard for diagnosis involves 3D imaging, 2D imaging by fundus photography is usually

17 For 3D imaging, a whole-mount staining and MUSE block-face i

18 It improves the 3D imaging ability of SPIM in resolving complex structur

19 By two-dimensional (2D) and 3D imaging after immunolabeling, both proteins also colo

20 g spatial transcriptomics, while large-scale 3D imaging analysis (around 1.2 million neighbourhoods)

21 of mouse embryos using a pipeline comprising 3D imaging and algorithms for morphometric analysis.

22 rom efficient, high-performance displays, to 3D imaging and all-organic spintronic devices.

23 Here, we use 3D imaging and analysis of dendritic spine morphometry t

24 d for intracellular dye filling, followed by 3D imaging and analysis of dendritic spine morphometry.

25 of 3D SS-OCT permits for the nondestructive 3D imaging and analysis of enamel crack behavior in whol

26 sed single-cell microinjections and advanced 3D imaging and analysis techniques to extend these findi

27 rough finding applications that benefit from 3D imaging and at the same time utilize the unique chemi

28 Integrating these systems with 3D imaging and biochemical assays revealed that ECs incr

29 Here, we use 3D imaging and cellular and clonal analysis, combined wi

30 inal cord, we also assessed CST-YFP mice for 3D imaging and found that YFP fluorescence in CST-YFP mi

31 A 3D imaging and image analysis pipeline was established t

32 Using 2D and 3D imaging and image segmentation, we characterized two

33 new pathway towards enabling high-resolution 3D imaging and inspires broader range application of het

34 Here we used real-time 3D imaging and knockout mouse models to clarify how part

35 Here we used real-time 3D imaging and KO mouse models to clarify how particles

36 place within a few hundred fs to ps, using a 3D imaging and laser pump-probe technique.

37 Leveraging single-cell RNA-sequencing, 3D imaging and lineage tracing, we classify the mouse lu

38 We demonstrate this combined 3D imaging and machine learning method can be used to un

39 We used time-lapse 3D imaging and mathematical modeling to assess root syst

40 This combined approach of 3D imaging and metabolomics provides a new strategy for

41 photography will broadly benefit high-speed 3D imaging and open up new avenues in various discipline

42 RV microvascular network were assessed using 3D imaging and quantification.

43 odel plant Arabidopsis thaliana, we combined 3D imaging and quantitative cell shape and cell lineage

44 We used time-lapse 3D imaging and quantitative image analysis to determine

45 ing key developmental stages with multiscale 3D imaging and single-cell transcriptomics, we delineate

46 al PTM were demonstrated for high-resolution 3D imaging and spectral identification of up to four chr

47 Terahertz scanning reflectometry, terahertz 3D imaging and terahertz time-domain spectroscopy have b

48 combination of comprehensive high resolution 3D imaging and tissue histology to identify abnormalitie

49 ith phase masks is a promising technique for 3D imaging and tracking.

50 ations in high-resolution three-dimensional (3D) imaging and accessible 3D analysis platforms.

51 uted tomography (SR-muCT) three-dimensional (3D) imaging and in-depth analysis of 3D structures were

52 cades was the introduction of 3-dimensional (3D) imaging and its evolution from slow and labor-intens

53 e pairs within a circadian gene module using 3D imaging, and found periodicity in the movement of clo

54 re using chromosome conformation capture and 3D imaging, and function using RNA-sequencing.

55 Optimized viral labeling, 3D imaging, and registration to a mouse digital neuroana

56 By combining lineage tracing, 3D imaging, and single-cell RNA sequencing (scRNA-seq) a

57 promise for scalable, large-FOV, high-speed, 3D imaging applications with compact device footprint.

58 le-photon lidar at video rates for practical 3D imaging applications.

59 Finally, this 3D imaging approach was used to capture different assemb

60 Using a 3D imaging approach with seedlings grown for various tim

61 Despite recent advances in 3D imaging approaches, our current knowledge of the spat

62 Using 3D imaging approaches, we established an integrative blu

63 adiological assessment techniques, including 3D imaging, artificial intelligence, and radiomics, and

64 imaging with PAT, there is still a need for 3D imaging at centimeter depths in real-time.

65 The study shows the potential of 3D imaging at high-resolution by phase-contrast tomograp

66 the detection axis enabled fast dual-channel 3D imaging at subcellular resolution without mechanical

67 on rate of 7.6 MHz, enabling densely sampled 3D imaging at video rate.

68 LSFM would enable gentle three-dimensional (3D) imaging at doubled resolution.

69 In gliding motility assays we performed 3D imaging based on fluorescence interference contrast m

70 d photon transport code, in a 3-dimensional (3D) imaging-based absorbed dose calculation for tumor an

71 A 3-dimensional (3D) imaging-based patient-specific dosimetry methodology

72 were highly statistically significant, with 3D imaging being superior in all cases.

73 Multifocal imaging (MFI) allows high-speed 3D imaging but is limited by the compromise between high

74 ection therefore opens up the possibility of 3D imaging by optical sectioning.

75 LD 3D imaging can make (82)Rb PET cardiac imaging more affo

76 Our simplified approach to 3D imaging can readily be extended to nonvisible waveban

77 The high lateral resolution and 3D imaging capabilities of SIMS combined with the multip

78 ntil recently, technical limitations such as 3D imaging capabilities, computational power and cost pr

79 ng is an optical method that enables various 3D imaging capabilities, yet it has not been implemented

80 chnique in the life sciences due to its fast 3D imaging capability of fluorescent samples with low ph

81 The 3D imaging capability of OCT and OCM provided complement

82 sign, high resolution, large depth of field, 3D imaging capability, scalability to shorter wavelength

83 Here we report the development of 3D imaging cluster Time-of-Flight secondary ion mass spe

84 cattering of metal nanoparticles can provide 3D imaging contrast in intact and transparent tissues.

85 Patients studied had both 2D-TEE and 3D imaging (contrast CT and/or 3D-TEE) of the aortic ann

86 Here, we use time-lapse and 3D imaging coupled with computational analysis to map th

87 3D imaging data necessitate 3D reference atlases for acc

88 NTD, named INMTD, which integrates omics and 3D imaging data to derive unconfounded subgroups of indi

89 3D imaging demonstrates the structural and cellular deta

90 how the standard microscope is an effective 3D imaging device.

91 nd should permit applications in noninvasive 3D imaging (e.g., the lymphatic system).

92 s via simple 2D images without sophisticated 3D-imaging equipment and with better than specialist per

93 ughput (500 to 1,000 cells/s) using a custom 3D imaging flow cytometer (3D-IFC) and dispensing cells

94 n and side scattering images obtained from a 3D imaging flow cytometer, we demonstrated key regulated

95 e use of an automatic slide loader automates 3D imaging for high sample-throughput.

96 tation of tumors and organs-at-risk (OAR) in 3D imaging for radiation-therapy planning is time-consum

97 In light of recent advances in 3D imaging for visualizing axons in unsectioned blocks o

98 ropose hybrid strategies that balance 2D and 3D imaging for well-rounded understanding of inter- and

99 achieved cross-talk-free three-dimensional (3D) imaging for four dyes 10 nm apart in emission spectr

100 nal phenomenon, it is hardly surprising that 3D imaging has had a significant impact on many challeng

101 Three-dimensional (3D) imaging has a significant impact on many challenges

102 mediastinoscopy, bronchoscopy, or endoscopy, 3D imaging helped in preprocedural planning.

103 Utilizing whole LN 3D imaging, histo-cytometry, and intravital 2-photon mic

104 3D imaging importantly allowed discernment of clusters o

105 This preparation enables direct 3D imaging in 500- to 750-nm sections with interferometr

106 l, and DESI-MS imaging can be used for lipid 3D imaging in an automated fashion to reveal heterogenei

107 n imaging, we must address the challenges of 3D imaging in an optically heterogeneous tissue that is

108 in CST-YFP mice is faint for clearing-based 3D imaging in comparison with fluorescence in Thy1-YFP-H

109 g the atomic scale, two-dimensional (2D) and 3D imaging in electron microscopy has become an essentia

110 he multifocus system enables high-resolution 3D imaging in multiple colors with single-molecule sensi

111 low-coherence interferometry for label-free 3D imaging in scattering tissue.

112 motivated development of three-dimensional (3D) imaging in both light and electron microscopies.

113 s to evaluate the accuracy of 3-dimensional (3D) imaging in detecting radiographic and morphological

114 Here, we used 3D imaging, in vivo electroporation and live-imaging tec

115 Quantitative 3D imaging is becoming an increasingly popular and power

116 situ, the availability of these methods for 3D imaging is expected to provide deeper insights into u

117 In addition, 3D imaging is extremely useful in the intraoperative and

118 However, such 3D imaging is still far from wide applications in biomed

119 Perhaps most important for 3D imaging is that the distance the image plane moves in

120 Another benefit of 3D imaging is the realistic and unique comprehensive vie

121 e of the myocardium, deep three dimensional (3D) imaging is difficult to achieve and structural analy

122 Accurate three-dimensional (3D) imaging is essential for machines to map and interac

123 Three-dimensional (3D) imaging is used to demonstrate that once these lipid

124 Here, we review the current state of 3D imaging mass spectrometry as well as provide insights

125 High-quality 3D imaging may be an ultimate solution for revealing the

126 In situ 3D imaging measurements provide unprecedented, quantitat

127 In conclusion, X-PCI is a 3D imaging method that can extend the amount of informat

128 (uCT) a widely applicable three-dimensional (3D) imaging method in studies of morphology and developm

129 Compared to other 3D imaging methods such as geometry modeling and 3D-scan

130 it to find its own niche alongside existing 3D imaging modalities through finding applications that

131 Advanced 3D imaging modalities, such as micro-computed tomography

132 As such, it provides a novel 3D imaging modality inheriting the advantages of imaging

133 s generally applicable to any time-dependent 3D imaging modality.

134 ltislice cross-sectional (three-dimensional [3D]) imaging modality that is characterized by poor soft

135 during the development of serial-sectioning 3D imaging MS and discusses the steps needed to tip it f

136 Serial 3D imaging MS has been steadily developing over the past

137 We demonstrate the feasibility of LAESI 3D imaging MS of metabolites in the leaf tissues of Peac

138 dvantage of the extra spatial dimension that 3D imaging MS offers.

139 Serial 3D imaging MS reconstructs 3D molecular images from seri

140 The future success of 3D imaging MS requires it to find its own niche alongsid

141 ourse was obtained with computed tomography, 3D imaging (NAVX), or intracardiac echocardiography.

142 g can computationally "freeze" the heart for 3D imaging, no previous algorithm has been able to maint

143 Here, we report quantitative 3D imaging of a whole, unstained cell at a resolution of

144 This work hence paves a way for quantitative 3D imaging of a wide range of biological specimens at na

145 pers in this issue move toward this goal via 3D imaging of active neurons across the entire mouse bra

146 Classic 2D and optical-clearing 3D imaging of an isolated adult zebrafish kidney were us

147 emonstrate the application of this method to 3D imaging of bacterial protein distribution and neuron

148 Reconstruction of the TIRF images enabled 3D imaging of biological samples with 20-nm axial resolu

149 graphy (OCT) allows label-free, micron-scale 3D imaging of biological tissues' fine structures with s

150 To facilitate high-throughput 3D imaging of brain gene expression, a new method called

151 of the leading methods for millimeter-scale 3D imaging of brain tissues at nanoscale resolution.

152 n situ hybridization (TEL-FISH) coupled with 3D imaging of buccal cell nuclei], providing high-resolu

153 diography (ICE) catheter allow for real-time 3D imaging of cardiac anatomy.

154 article we review several methodologies for 3D imaging of cells and show how these technologies are

155 Many biological investigations require 3D imaging of cells or tissues with nanoscale spatial re

156 lectron microscopy (EM) approach that allows 3D imaging of cellular structures in near-native, frozen

157 tudy demonstrates the utility of FIB-SEM for 3D imaging of collagen gels and quantitative analysis of

158 ated data-processing algorithms, can achieve 3D imaging of collection objects without the need for a

159 Electron cryo-tomography (cryo-ET) enables 3D imaging of complex, radiation-sensitive structures wi

160 several orders of magnitude that enable the 3D imaging of dilute biomolecules including gases.

161 Here we report 3D imaging of dislocations in materials at atomic resolu

162 tion kinetics, and the surface profiling and 3D imaging of dye sensitized TiO2 films.

163 However, quantitative 3D imaging of ECM mechanics with cellular-scale resoluti

164 3D imaging of ECM was performed via the newly developed

165 (PATTERN), for non-destructive, high-speed, 3D imaging of ex vivo rodent, ferret, and non-human prim

166 Finally, 3D imaging of fixed cells in culture medium is demonstra

167 rived from confocal airyscan high-resolution 3D imaging of fluorescence-tagged keratin filaments.

168 We developed an image analysis pipeline for 3D imaging of GEMs in the context of large, multinucleat

169 scence Microscopy (LSFM) for high-resolution 3D imaging of healthy and ADPKD-induced mouse kidneys, e

170 s are difficult to determine as quantitative 3D imaging of individual dopant atoms is a major challen

171 n of substrate and lipid tracers in confocal 3D imaging of individual proteolipobeads.

172 -field technologies, we further demonstrated 3D imaging of intestine in vivo (3D-TIP).

173 to be compatible with fixation thus allowing 3D imaging of LDs in their cytoplasm environment.

174 nally, TP-alpha was successfully applied for 3D imaging of live islets by staining alpha cell directl

175 LS-RESOLFT nanoscopy offers wide-field 3D imaging of living biological specimens with low light

176 Cryo-electron tomography (cryo-ET) enables 3D imaging of macromolecular structures.

177 scopy opens a vista of new opportunities for 3D imaging of materials dynamics on their intrinsic subm

178 Nanometer-scale 3D imaging of materials properties is critical for under

179 The 3D imaging of mature field-grown root crowns showed that

180 We have built an optical lens system for 3D imaging of objects up to 6 mm wide and 3 mm thick wit

181 ed to investigate the diagnostic accuracy of 3D imaging of OCT for proximal caries in posterior teeth

182 mp-probe spectroscopy permits nondestructive 3D imaging of paintings with molecular and structural co

183 ntrast agent and pH-responsive nanoprobe for 3D imaging of pH distribution.

184 two-dimensional (2D) imaging and three-color 3D imaging of proteins in fixed cells.

185 Macro-scan images of the brain and 3D imaging of selected brain regions were performed.

186 ible and versatile clearing procedure called 3D imaging of solvent-cleared organs, or 3DISCO, which i

187 e allows fast, high-contrast, and convenient 3D imaging of structures that are hundreds of microns be

188 3D imaging of the bone vasculature is of key importance

189 o single-detector row CT for multiplanar and 3D imaging of the central airways.

190 labeling technologies prohibits quantitative 3D imaging of the entire contents of cells.

191 eliable method of generating high-resolution 3D imaging of the fetal vasculature.

192 easily recognized via surface profiling and 3D imaging of the films.

193 hich can be collected by the transducers for 3D imaging of the hemoglobin with a high spatial resolut

194 Sixteen patients underwent 3D imaging of the prostate gland with a 3D endorectal pr

195 ngiography (OCTA) is a noninvasive method of 3D imaging of the retinal and choroidal circulations.

196 3D X-ray histology allows for nondestructive 3D imaging of tissue microstructure, resolving structura

197 Thus, 3D imaging of whole cells (or even large organelles) sti

198 aring protocol that removes melanin allowing 3D imaging of whole eyes and visual pathways.

199 Here, we perform 3D imaging of young and aging vascular beds.

200 microscopy, enable rapid three-dimensional (3D) imaging of biological specimens, such as whole mouse

201 , our platform allows for three-dimensional (3D) imaging of bioparticles without using complex confoc

202 Three-dimensional (3D) imaging of delicate, moving soft-tissue body parts i

203 roviding high-resolution, three-dimensional (3D) imaging of fluorescent molecules.

204 py, as we demonstrated by three-dimensional (3D) imaging of fluorescent pollens and brain slices.

205 ) enables native-contrast three-dimensional (3D) imaging of fully hydrated, cryogenically preserved b

206 d that has enabled successful 3-dimensional (3D) imaging of intact tissues with high-resolution and p

207 Fast, nondestructive three-dimensional (3D) imaging of live suspension cells remains challenging

208 we successfully performed three-dimensional (3D) imaging of mammalian nuclei by combining coherent x-

209 Three-dimensional (3D) imaging of molecular distributions offers insight in

210 High-speed, large-scale three-dimensional (3D) imaging of neuronal activity poses a major challenge

211 ctron tomography provides three-dimensional (3D) imaging of noncrystalline and crystalline equilibriu

212 f efficient protocols for three-dimensional (3D) imaging of ovaries.

213 non-destructive tool for three-dimensional (3D) imaging of strain and defects in crystals that are s

214 High-definition and three-dimensional (3D) imaging of the normal retina and optic nerve head we

215 o afford large volumetric three-dimensional (3D) imaging of tissues with deep-axial penetration depth

216 Here we present three-dimensional (3D) imaging of vacuum fluctuations in a high-Q cavity ba

217 ve-cell imaging with 2-photon microscopy and 3D imaging, of Wt1-EGFP transgenic mice.

218 re tested from the pseudo three-dimensional (3D)-imaging perspective.

219 This high-throughput 3D imaging platform could in general be quite valuable f

220 Here, we introduce a quantitative 3D imaging platform to enable the visualization and anal

221 nd ranging system could serve as a universal 3D imaging platform.

222 LSO PET detector technology permits fast 3D imaging protocols whereby weight-based emission scan

223 stimated strain can be insightful to improve 3D imaging protocols, and the computer code of LWM could

224 attering layer dimensions and incorporates a 3D imaging quality test, representing a single cell with

225 However, 3D imaging remains limited to anisotropic resolution and

226 fluorophores opens up avenues for improving 3D imaging resolution beyond the Rayleigh diffraction li

227 raphy (TOF-MRA)-which is well suited to high 3D imaging resolutions-has not been applied to imaging t

228 We also obtained sharp, specific 2D and 3D imaging results for early stage apoptosis in breast c

229 Finally, we demonstrate 3D imaging results of multiple static and moving objects

230 Microangiography and 3D imaging revealed patchy perfusion of Egfl7(-/-) place

231 In experimental steatohepatitis, 3D imaging reveals a severe portal vein contraction, spa

232 the positional guidance of a SPECT/CT-based 3D imaging roadmap, in this process we studied to which

233 suppression involves multiple cell types and 3D imaging shows that seemingly localized 2D features su

234 neovascularization after stroke using a new 3D imaging software program.

235 CT data were analyzed with workstation-based 3D imaging software, with a thresholding procedure based

236 ing confocal microscopy and high-performance 3D imaging software.

237 ' single-objective, light-sheet geometry and 3D imaging speeds enable roving image acquisition, which

238 be interlaced with SIMS depth profiling and 3D imaging sputtering and analysis cycles, which is not

239 Using a novel, 3D imaging strategy, we visualized live oxytocin-induced

240 However, recent 3D imaging studies demonstrate that mitochondria are par

241 A unique phased-array volumetric 3D imaging system developed at the Duke University Cente

242 this work, we report a high-speed FMCW based 3D imaging system, combining a grating for beam steering

243 rsion, and pelvic rotation using a validated 3D imaging system.

244 tector array, consisting of 512 pixels, in a 3D imaging system.

245 n powerful and extremely accurate high-speed 3D imaging systems ubiquitous in nowadays science, indus

246 Three-dimensional (3D) imaging systems capture detailed and accurate measur

247 However, this 3D imaging technique is computationally bottlenecked by

248 fully understood and a spectrally sensitive 3D imaging technique is needed to visualize the excitati

249 In this protocol, we describe a 3D imaging technique known as 'volume electron microscop

250 al coherence tomography (OCT) is an emerging 3D imaging technique that allows quantification of intri

251 Photometric stereo is a three dimensional (3D) imaging technique that uses multiple 2D images, obta

252 using a novel high-resolution 3-dimensional (3D) imaging technique.

253 innovative computer-aided three-dimensional (3D) imaging technique.

254 multi-physics modeling methods and advanced 3D imaging techniques enable rapid, real-time transforma

255 The spatial resolution of 3D imaging techniques is often balanced by the achievabl

256 so employed optical coherence tomography and 3D imaging techniques to assess and compare whole or bro

257 X-ray-based 3D-imaging techniques have gained fundamental significan

258 Although numerous 3D imaging technologies exist, each addressing niche app

259 is study, we examined the feasibility of two 3D imaging technologies, optical coherence tomography (O

260 Three-dimensional (3D) imaging technologies are beginning to have significa

261 3D-imaging technologies provide measurements of terrestr

262 Advances in 3D imaging technology are transforming how radiologists

263 3D imaging technology is becoming more prominent every d

264 Using the same nanometer scale 3D imaging technology on appropriately stained frog neur

265 Cryo-Electron Tomography (cryo-ET) is a 3D imaging technology that enables the visualization of

266 ng, and fluorescence-preserving workflow for 3D imaging that bridges section-based and whole-organ st

267 provements have led to real-time full-volume 3D imaging that is no longer prone to the artifact issue

268 Here, we reveal through real-time and 3D imaging the formation of a single decagonal quasicrys

269 It can perform snapshot 3D imaging through a thin optical mask with a scalable f

270 specificity and sensitivity for noninvasive 3D imaging through tissues and whole animals.

271 omise for applications in three-dimensional (3D) imaging through the creation of flexible X-ray detec

272 ation to model immune-mediated GI damage and 3D imaging to analyze T cell localization, we found that

273 he cytoskeletal regulator Abelson (Abl) with 3D imaging to explore how the distinct cellular morphoge

274 tic tracing with high-resolution whole-brain 3D imaging to generate a comprehensive spatiotemporal ma

275 n analysis, cytogenetics, immunocytology and 3D imaging to genetically map and characterize the barle

276 ular cell labeling, parabiosis and multiplex 3D imaging to identify a population of group 3 ILCs in m

277 a genomically accurate 22q11.2DS model, and 3D imaging to identify and quantify phenotypes that coul

278 o good energy resolution, which is needed in 3D imaging to minimize scatter and random coincidences.

279 ly associated with tapetal function, we used 3D imaging to quantify geometric and textural features o

280 Here, we perform comparative 3D imaging to understand age-related perturbations of th

281 lic driving protocols and three-dimensional (3D) imaging to correlate the global mechanical response

282 Additionally, 3D imaging using focused ion beam scanning electron micr

283 equirement for performing three-dimensional (3D) imaging using optical microscopes is that they be ca

284 In particular, 3D imaging was used to identify the carotid bifurcation

285 -derived volume and length estimates through 3D-imaging, water displacement, and post-mortem measurem

286 With pseudodynamic 3D imaging, we derive individual parameters that are cen

287 Using intravital dye labeling and 3D imaging, we discovered that systems-level vascular pa

288 Using 3D imaging, we find that during fetal development the vi

289 ngle cell RNA-sequencing and high resolution 3D imaging, we further demonstrate that organoid culture

290 g platform that incorporates high-resolution 3D imaging, we identify phenotypes at multiple time poin

291 dition, using single-cell RNA-sequencing and 3D imaging, we show that PM organoids both transcription

292 generate efficient XEPL for high-resolution 3D imaging, which is attributed to a lack of strategies

293 e investigated by immunohistochemistry-based 3D imaging, whole-mount fluorescence staining, and real-

294 3D imaging with a distance resolution of 1.7 cm is achie

295 he first demonstration of analyte-responsive 3D imaging with LSFM, highlighting the utility of combin

296 tifacts, establishing a standard for routine 3D imaging with phase contrast.

297 ocardial tissue suitable for high resolution 3D imaging, with implications for the study of complex c

298 gy is capable of isotropic, single live-cell 3D imaging, with the potential to perform large-scale mo

299 dvantages of low cost, portability, and live 3D imaging without offline reconstruction.

300 3D imaging yielded better lesion detectability than 2D (