ライフサイエンスコーパス: three-dimensional image

1 , and quantitatively false-colored to form a three-dimensional image.

2 backprojection algorithm applied to generate three-dimensional images.

3 valve areas obtained by planimetry from the three-dimensional images.

4 rendered, and the images were converted into three-dimensional images.

5 z-score maps rendered on two-dimensional and three-dimensional images.

6 onstructing high-quality two-dimensional and three-dimensional images.

7 ns with the database patterns; and a lack of three-dimensional images.

8 of these projections to obtain high quality three-dimensional images.

9 evaluated in control and diabetic rats using three-dimensional images.

10 re probed by means of laser manipulation and three-dimensional imaging.

11 ces thus obtained can be used to reconstruct three-dimensional images, a capability which is particul

12 ces thus obtained can be used to reconstruct three-dimensional images, a capability which is particul

13 and a confocal microscope that provides fast three-dimensional image acquisition.

14 s of online measurement, remote sampling and three-dimensional imaging, all of which are attractive f

15 Three-dimensional images allowed visualization of the ra

16 Morphological and three dimensional image analyses revealed significant (P

17 An automated three-dimensional image analysis method was validated th

18 ourse confocal laser scanning microscopy and three-dimensional image analysis of actively growing bio

19 We used cryoelectron microscopy and three-dimensional image analysis to visualize T3D virion

20 Quantitative three-dimensional image analysis, combined with a genome

21 ional nodules at a dedicated workstation for three-dimensional image analysis.

22 biological image classification of two- and three- dimensional images and ROIs.

23 ent dye filling, followed by high-resolution three-dimensional imaging and analysis of dendritic arbo

24 d for intracellular dye filling, followed by three-dimensional imaging and analysis of dendritic arbo

25 ne expression in a model system, we employed three-dimensional imaging and chromatin immunoprecipitat

26 The widespread availability of three-dimensional imaging and computational power has fo

27 Using a combination of ultrahigh-resolution three-dimensional imaging and two-dimensional solid-stat

28 ts in myocardial contrast perfusion imaging, three-dimensional imaging, and strain-rate echocardiogra

29 ed spectro-microtomography, a nondestructive three-dimensional imaging approach that reveals the dist

30 n human intestinal disease, we established a three-dimensional imaging approach to characterize the l

31 Three-dimensional images are shown at an isotropic resol

32 r echocardiographic technologies (strain and three-dimensional imaging) are promising, but require fu

33 MATERIAL/METHODS: Simulated three-dimensional images, as well as the real microtomog

34 cal constraints that will prevent whole-cell three-dimensional imaging at <10 nm resolution.

35 ase evolution panorama via spectroscopic and three-dimensional imaging at multiple states of charge f

36 with the goal being subcellular resolution, three-dimensional images, at depth, in living samples.

37 n the world of diagnostic imaging (typically three-dimensional imaging but performed separately from

38 d because of its ability to produce accurate three-dimensional imaging, but limitations such as radia

39 t faithfully preserves molecular structures, three-dimensional imaging by electron tomography, and im

40 Three-dimensional images can be assessed qualitatively a

41 We show that high quality three-dimensional imaging can be realized at depths beyo

42 Using cryo-electron tomography combined with three-dimensional image classification and averaging, we

43 Custom software created three-dimensional images (computer models) from the scan

44 nd fast automated segmentation algorithm for three-dimensional images containing biological objects.

45 a radiologist as being comparable to that of three-dimensional images created with manual editing.

46 Three-dimensional image data sets were acquired from NIH

47 Average three-dimensional image data sets were constructed for e

48 MPLSM allows high-resolution, three-dimensional image data to be collected deeper with

49 of the system hardware could enable low-cost three-dimensional imaging devices for precision ranging

50 thms based on principles other than fitting, three-dimensional imaging, dipole imaging and techniques

51 Three-dimensional imaging disclosed that STOCless sparks

52 Advanced postprocessing, including three-dimensional image display, multimodality image fus

53 d for execution by either two-dimensional or three-dimensional imaging display (30 by each method).

54 OpenSimRoot can model three-dimensional images from magnetic resonance imaging

55 This work clearly shows that three-dimensional images from MPLSM of endogenous tissue

56 as possible, which is optimally achieved by three-dimensional imaging given the heterogeneity of can

57 randomised comparison of two-dimensional and three-dimensional imaging in elective laparoscopic chole

58 orneal epithelium and nerve morphology using three-dimensional imaging in vivo and in situ in a strep

59 learing methods promise to provide exquisite three-dimensional imaging information; however, there is

60 From the random projection views, a three-dimensional image is reconstructed, enabling the s

61 es are digitized, and after postprocessing a three-dimensional image is reconstructed.

62 Time-of-flight three-dimensional imaging is an important tool for appli

63 role of new technology such as harmonic and three-dimensional imaging is yet to be determined.

64 ML follows the XML standard to store two- or three-dimensional image metadata, plant and root propert

65 This three-dimensional imaging method has potential applicati

66 uorescently labeled objects contained within three-dimensional images obtained from laser scanning co

67 -voltage electron microscopy and analyze the three-dimensional images obtained from thick sections of

68 The three-dimensional images obtained highlighted the layere

69 aine binding specificity by biopolymers, the three-dimensional images obtained reflect the properties

70 Three dimensional images of 157 deceased individuals (37

71 Visualizing and analyzing large three dimensional images of intact tissue is a challengi

72 ch to assign cell names to each nucleus in a three-dimensional image of an L1 worm.

73 erial EM sections were used to reconstruct a three-dimensional image of germinal granule distribution

74 A three-dimensional image of the density, obtained by inve

75 ere used to reconstruct a computer-generated three-dimensional image of the great vessels and ductus

76 The three-dimensional image of the organ then was fused with

77 Electron cryotomography (ECT) can produce three-dimensional images of biological samples such as i

78 Cryo-electron tomography (CET) produces three-dimensional images of cells in a near-native state

79 uracy and precision of a system for creating three-dimensional images of dental arches.

80 lution algorithm to generate high-resolution three-dimensional images of GFP fluorescence in the livi

81 High-resolution three-dimensional images of immunofluorescence were obta

82 mally invasive technique was used to collect three-dimensional images of intraocular vessels in vivo

83 th cell diameter by simultaneously analyzing three-dimensional images of MreB and cell shape.

84 Three-dimensional images of reflecting interfaces throug

85 Here we present three-dimensional images of seismic reflectivity beneath

86 Three-dimensional images of shear-wave velocity beneath

87 sources, can be used to obtain quantitative three-dimensional images of strain.

88 We present three-dimensional images of structurally complex collage

89 raphy scans can be used to generate accurate three-dimensional images of structures, such as skulls,

90 lical image analysis was used to reconstruct three-dimensional images of TCs at approximately 20 A re

91 Here, three-dimensional images of the attachment organelle wer

92 Three-dimensional images of the colon simulating those o

93 Three-dimensional images of the colon simulating those o

94 Three-dimensional images of the gallbladder were acquire

95 tion sources, can be inverted to obtain full three-dimensional images of the interior density within

96 al dye MitoTracker Green were used to obtain three-dimensional images of the mitochondrial network in

97 A staged series of three-dimensional images of the vascular system were col

98 A method of three-dimensional imaging of blood vessels was used in t

99 ent echo magnetic resonance sequence for the three-dimensional imaging of brain iron-induced contrast

100 th use of a pulse sequence for time-resolved three-dimensional imaging of contrast material kinetics.

101 d electronic devices in a silicon chip); and three-dimensional imaging of cryogenically fixed biologi

102 using electron and X-ray techniques, in situ three-dimensional imaging of defect dynamics remains cha

103 Three-dimensional imaging of dental tissues will have a

104 We report three-dimensional imaging of dislocation dynamics in ind

105 Quantitative three-dimensional imaging of lattice strain on the nanom

106 High resolution three-dimensional imaging of live cells containing both

107 has reached nanoscale resolution for in situ three-dimensional imaging of macromolecular complexes an

108 ty to the single-spin level, and thus enable three-dimensional imaging of macromolecules (for example

109 Three-dimensional imaging of pre-symptomatic SOD1 mouse

110 photobleaching correction for timelapse and three-dimensional imaging of protein-protein interaction

111 nce force microscopy, which has demonstrated three-dimensional imaging of proton NMR with resolution

112 enhancing agents, enable the high-resolution three-dimensional imaging of relatively small features.

113 (MRI) are noninvasive and allow high-quality three-dimensional imaging of roots in soil.

114 l using the method of immunolabeling-enabled three-dimensional imaging of solvent-cleared organs (iDI

115 variation of Fourier domain OCT that allows three-dimensional imaging of the angle analogous to goni

116 ment was examined by performing quantitative three-dimensional imaging of the capillary networks that

117 atively evaluate the increase in fibrosis by three-dimensional imaging of the collagen network in the

118 Three-dimensional imaging of the Earth's interior, calle

119 However, these techniques cannot offer three-dimensional imaging of the formation or movement o

120 Here we report three-dimensional imaging of the generation and subseque

121 arious time intervals after transplantation, three-dimensional imaging of the graft was performed by

122 The current state of three-dimensional imaging of the right ventricle will be

123 sive number of microvessels in these tumors; three-dimensional imaging of the tumorigenic vasculature

124 Three-dimensional imaging of viral gene expression in th

125 We have developed a method for three-dimensional imaging of whole-mount, unsectioned ma

126 els of human glioma and can be rendered into three-dimensional images offering exquisite anatomic det

127 head and torso and of a mouse lung based on three-dimensional images processed via our software Angi

128 Three-dimensional imaging provides unique images and pro

129 Average three-dimensional image quality at three sites in the co

130 aphy as well as cryo-electron microscopy and three-dimensional image reconstruction (cryo-reconstruct

131 used cryo-electron microscopy (cryo-EM) and three-dimensional image reconstruction (cryo-reconstruct

132 matrix of 128(3) with (2 mm)3 voxels, using three-dimensional image reconstruction algorithms.

133 Three-dimensional image reconstruction and videodensitom

134 examined using cryo-electron microscopy and three-dimensional image reconstruction both at an approx

135 We have used electron cryomicroscopy and three-dimensional image reconstruction methods to examin

136 Three-dimensional image reconstruction obtained by optic

137 digm which has the potential to perform true three-dimensional image reconstruction of biological tis

138 by carrying out cryo-electron microscopy and three-dimensional image reconstruction of myosin filamen

139 We have used cryoelectron microscopy and three-dimensional image reconstruction techniques to exa

140 , determined by cryo-electron microscopy and three-dimensional image reconstruction to 18.0- to 8.5-A

141 We used electron cryomicroscopy and three-dimensional image reconstruction to determine the

142 Here we have used electron microscopy and three-dimensional image reconstruction to observe the ef

143 nction, we have used electron microscopy and three-dimensional image reconstruction to reveal the loc

144 We used electron cryo-microscopy and three-dimensional image reconstruction to study the icos

145 We have used cryoelectron microscopy and three-dimensional image reconstruction to study this com

146 Cryo-electron microscopy and three-dimensional image reconstruction were used to defi

147 Cryo-electron microscopy and three-dimensional image reconstruction were used to solv

148 Confocal microscopy and three-dimensional image reconstruction were used to stud

149 teraction by using cryo-electron microscopy, three-dimensional image reconstruction, and molecular mo

150 Using cryoelectron microscopy, three-dimensional image reconstruction, and molecular mo

151 ptor complex by cryo-electron microscopy and three-dimensional image reconstruction, combined with fi

152 e binding assay with confocal microscopy and three-dimensional image reconstruction, spatially resolv

153 Using electron microscopy and three-dimensional image reconstruction, the association

154 Using live imaging and three-dimensional image reconstruction, we demonstrate t

155 eans of cryoelectron microscopy (cryoEM) and three-dimensional image reconstruction.

156 2.8 to 3.0 A by cryo-electron microscopy and three-dimensional image reconstruction.

157 o that in virions by electron microscopy and three-dimensional image reconstruction.

158 cryogenic electron microscopy (cryo-EM) and three-dimensional image reconstruction.

159 arly by cryo electron microscopy followed by three-dimensional image reconstruction.

160 ion by means of cryo-electron microscopy and three-dimensional image-reconstruction techniques.

161 Three-dimensional image reconstructions of confocal z-sc

162 Electron cryo-microscopy and three-dimensional image reconstructions of F170A and F17

163 Using laser scanning confocal microscopy and three-dimensional image reconstructions of GUVs labeled

164 Three-dimensional image reconstructions of homogenous po

165 The three-dimensional image reconstructions provide a molecu

166 e cells are spread across the sample volume, three-dimensional imaging requires a light-sheet with a

167 Three-dimensional imaging reveals that Ash1 mRNA is asse

168 As a full-time three-dimensional imaging scanner with a very large axia

169 Three-dimensional imaging showed that adhesions formed b

170 resent time, the development of multiplanar, three-dimensional imaging shows great promise for more c

171 atinocytes in the epidermis were observed in three-dimensional image stacks after topical administrat

172 r neural expression patterns in thousands of three-dimensional image stacks of individual brains requ

173 Three-dimensional image stacks of normal (n = 13), preca

174 Quantitative three-dimensional imaging studies revealed that a plexus

175 Here we show a modified time-of-flight three-dimensional imaging system, which can use compress

176 Conventional time-of-flight three-dimensional imaging systems frequently use a raste

177 The three-dimensional imaging technique was applied to urica

178 As a revolutionary three-dimensional imaging technique, holography has attr

179 -ray microtomography (XMT), a nondestructive three-dimensional imaging technique, was applied to demo

180 Using high-resolution, three-dimensional imaging techniques, we determined dire

181 e demonstrate that, in addition to providing three-dimensional images that clearly delineate probe di

182 been extended to live cells and multicolor, three-dimensional imaging, thereby providing exquisite s

183 ntroduce a concept that enables parallelized three-dimensional imaging throughout large volumes with

184 Fast acquisition of three-dimensional image time series has now become possi

185 , we used cryo-electron tomography to obtain three-dimensional images to elucidate a role for HA acyl

186 monitored using high-speed, high-sensitivity three-dimensional imaging to track individual mitochondr

187 d imaging system is presented that generates three-dimensional images using a stationary, real acoust

188 The results of three-dimensional imaging using a grid of L-TMA measurem

189 Three-dimensional imaging using electron tomography allo

190 Three-dimensional image volumes were then collected.

191 Three-dimensional imaging was performed in 43 specimens

192 g optical tweezers operated independently of three-dimensional imaging, we inserted interstitials in

193 Axial, multiplanar, and three-dimensional images were evaluated to determine whe

194 The three-dimensional images were recorded with confocal and

195 Reformatted two-dimensional and three-dimensional images were then graded for polyp dete

196 pulation workstation integrating two-photon, three-dimensional imaging with a high-force, uniform-gra

197 structural evidence, from rapid, live-cell, three-dimensional imaging with confirmation from high-re

198 As three-dimensional imaging workstations move from the adv