ライフサイエンスコーパス: three dimension

1 of different experimental assays (in two and three dimensions).

2 erning cell types and scaffold properties in three dimensions.

3 d correlation of these nanoparticle doses in three dimensions.

4 ar shapes and followed their displacement in three dimensions.

5 ty of interpreter services as variable along three dimensions.

6 mic structure can be routinely determined in three dimensions.

7 ition in two dimensions is different than in three dimensions.

8 ng can provide a similar performance for all three dimensions.

9 variety of photonic topological phenomena in three dimensions.

10 object to be reconstructed and visualised in three dimensions.

11 elaxation time are very different in two and three dimensions.

12 ish (Danio rerio) neuromuscular junctions in three dimensions.

13 ular imaging with cellular resolution in all three dimensions.

14 dimensions, whereas it is very pronounced in three dimensions.

15 linking (gamma-CD)6 body-centered cuboids in three dimensions.

16 , actin, and the Golgi apparatus dynamics in three dimensions.

17 ribed by the nearest-neighbor Ising model in three dimensions.

18 ices and functional motifs are positioned in three dimensions.

19 onstruct the efferent pathways of the LHb in three dimensions.

20 modeling of heat transfer and fluid flow in three dimensions.

21 ements with the surface plasmon resonance in three dimensions.

22 he individual localisation precisions in all three dimensions.

23 sensor that is able to measure the field in three dimensions.

24 d to have similar characteristics in two and three dimensions.

25 on yields images with high resolution in all three dimensions.

26 atment affects melanoma cell MMP activity in three dimensions.

27 relaxation time in two dimensions but not in three dimensions.

28 rstand how OECs interact with other cells in three dimensions.

29 hting the importance of studying a system in three dimensions.

30 pulate microscopic objects, contact-free, in three dimensions.

31 high modal purity, which are well defined in three dimensions.

32 ecovered, each of which has been prepared in three dimensions.

33 through {W-O-TM-O-W} bridges in one, two, or three dimensions.

34 can nondestructively probe these changes in three dimensions.

35 optical single molecule tracking in two and three dimensions.

36 reement with our predictions in both two and three dimensions.

37 mage the diffusion layers of UMEs in two and three dimensions.

38 framework to simulate zebrafish swimming in three dimensions.

39 ing multiple materials, known as bioinks, in three dimensions.

40 ctive niche signaling regulates cell fate in three dimensions.

41 sicles, and crystallization of tetrahedra in three dimensions.

42 obes for understanding disease mechanisms in three dimensions.

43 r the investigation of biological systems in three dimensions.

44 caled down to less than 10 nm and stacked in three dimensions.

45 aggregates of GFP-conjugated Tau protein in three dimensions.

46 it is notoriously difficult to conduct it in three dimensions.

47 elative positioning of RRE2 substructures in three dimensions.

48 voidspace distributions to be quantified in three dimensions.

49 alize optical absorption contrast in vivo in three dimensions.

50 d magnetic objects simultaneously in two and three dimensions.

51 in 2D space; this work extends the model to three dimensions.

52 oot systems were imaged and reconstructed in three dimensions.

53 pitulation of this exquisite architecture in three dimensions.

54 servations of single nanotube endocytosis in three dimensions.

55 RBC stretching tests by optical tweezers in three dimensions.

56 ieve twice diffraction-limited resolution in three dimensions.

57 ptogenetic activation of selected neurons in three dimensions.

58 orks often extend hundreds of micrometers in three dimensions.

59 ting in a well-ordered, oriented emulsion in three dimensions.

60 s the search for homology by sampling DNA in three dimensions.

61 a complex network of atomic interactions in three dimensions.

62 n, and phototoxicity, made more difficult in three dimensions.

63 than 75% of cases and can span a surface or three dimensions.

64 ity while imaging at the micrometre scale in three dimensions.

65 article and several grains are identified in three dimensions.

66 , and dendritic arbors were reconstructed in three dimensions.

67 membranes require high spatial resolution in three dimensions.

68 includes identification of host proteins in three dimensions.

69 s formed by interacting electrons in two and three dimensions.

70 sufficient information to embed chromatin in three dimensions.

71 sulin granules in intact cell populations in three dimensions.

72 ing, Cdc42 is essential in ECM remodeling in three dimensions.

73 rocesses in soft matter, which take place in three dimensions.

74 structured droplet of chiral active fluid in three dimensions.

75 nanoparticle encapsulated inside the cage in three dimensions.

76 elative to their neighbors, in contrast with three dimensions.

77 ugh providing additional hydraulic routes in three dimensions.

78 ntly deposit and organize the ECM in two and three dimensions.

79 ating from adjacent L5B columns in the BC in three dimensions.

80 find differences between two dimensions and three dimensions.

81 track complex pseudopods of cells moving in three dimensions.

82 ed at nanometre-scale spatial resolutions in three dimensions.

83 rized stage system to cancel brain motion in three dimensions.

84 terize, and manipulate neuronal ensembles in three dimensions.

85 f tissue can specify the shape it assumes in three dimensions.

86 chromosome axes to high spatial precision in three dimensions.

87 ed with histones and DNA-binding proteins in three dimensions.

88 lows based on the NCCM model both in two and three dimensions.

89 and establishing directional interactions in three dimensions.

90 at cell-scale resolution over millimeters in three dimensions.

91 t lines-dislocation loops-that are unique to three dimensions.

92 hile also describing nuclear position in all three dimensions.

93 ol the structure of silk proteins in two and three dimensions.

94 rete stochastic biochemical systems in up to three dimensions.

95 meras enabled marker motion to be tracked in three dimensions.

96 h overlapping and nonoverlapping clusters in three dimensions.

97 t of plane, with long correlation lengths in three dimensions.

98 than two, creating a synchronised motion in three-dimensions.

99 r features with unprecedented detail in full three-dimensions.

100 folk knowledge about animals is dominated by three dimensions: (1) level of cognitive complexity or "

101 bacterial populations growing in colonies in three dimensions (3-d).

102 al model of intracellular calcium cycling in three-dimensions (3-D), which incorporates high resoluti

103 nd to encounter resources more frequently in three dimensions (3D) (for example, arboreal and pelagic

104 non-invasively, in situ, quantitatively, in three dimensions (3D) and in real time.

105 granules have not been studied in detail in three dimensions (3D) in unmodified samples.

106 ying principles for hydrodynamic focusing in three dimensions (3D) using miscible fluids and the appl

107 tral imaging to map molecular composition in three dimensions (3D) with submicron resolution.

108 RNP filaments were traced in three dimensions (3D), and their total length was calcul

109 VLPs) and virions tethered to human cells in three dimensions (3D).

110 ons at supramolecular and cellular scales in three dimensions (3D).

111 Here we image the developing mouse lung in three-dimensions (3D) and show that two nested developme

112 for homogeneous, high electron densities in three-dimensions (3D).

113 nsions but without long-range periodicity in three-dimensions (3D).

114 For species that move freely in three dimensions, a face-centered cubic lattice is best.

115 rained (rigid) collections of constraints in three dimensions, a problem for which there is no known

116 to image the activity of neural circuits in three dimensions across multiple areas in the brain.

117 regions of efficient cathodoluminescence in three dimensions across visible and near-infrared wavele

118 ions and fractionalization of excitations in three dimensions all stem from a simple classical Hamilt

119 ated method for full organ reconstruction in three dimensions, allowing visualization of intact mouse

120 to recreate the tumor-vascular interface in three-dimensions, allowing for high resolution, real-tim

121 rotating light-sheet and detection planes in three dimensions and (ii) a computational method that co

122 tions in the mineral content distribution in three dimensions and at the nanometre scale.

123 cluding progressing these models from two to three dimensions and developing new tools for model vali

124 ods to precisely locate nanoscale objects in three dimensions and for the formation of rigorous struc

125 oped tomography, we imaged a human breast in three dimensions and identified a malignant cancer with

126 to examine the microanatomy of the cornea in three dimensions and in large tissue volumes.

127 for finite Morse index solutions in two and three dimensions and suggest a possible program of class

128 ds increase approximately linearly along all three dimensions and that detection accuracy is unaffect

129 -molecule localization microscopy imaging in three dimensions and two colors.

130 -Hess scale, aneurysm localization, aneurysm three dimensions and volume, neck width, sac-to-neck rat

131 r inability to position organic molecules in three dimensions and with sub-1 micrometer resolution.

132 Simulating the quantum evolution in three-dimensions and time, we show that imprinting such

133 m by imaging endogenous clathrin (in two and three dimensions) and apply the method to find the previ

134 Both are preserved in three dimensions, and are imaged with the aid of X-ray m

135 id material would extend those properties to three dimensions, and be useful in energy storage and na

136 are clustered on chromosomes in both two and three dimensions, and interactions with active enhancers

137 allows imaging of the retinal circulation in three dimensions, and macular pigment optical density (M

138 ippocampal place-cell maps are metric in all three dimensions, and might be composed of 2-D and 3-D f

139 rescence imaging, 7 x 7 x 3.5 mum in OCT in three dimensions, and the current speed of imaging is up

140 high-resolution shearing-box simulations in three dimensions, and with global two-dimensional simula

141 geted patchy colloidal assemblies in two and three dimensions are stable, thus overcoming the difficu

142 erial to organize plasmonic nanoparticles in three dimensions, as well as fuel for driving the metamo

143 crystallinity, multiphasic distributions in three dimensions, as well as lifetimes, structures and e

144 b-diffraction imaging at arbitrary points in three dimensions, as well as the ability to track moving

145 ractive indices that are isotropic in two or three dimensions at microwave frequencies have been achi

146 locks where targets were presented in one of three dimensions: auditory location, pitch, or visual br

147 acterizing the motility of microorganisms in three dimensions based on standard imaging microscopy.

148 for carrying out studies of cell sorting in three dimensions, because of its unique ability to regen

149 o answer experimentally: measuring forces in three dimensions, between deeply buried grains, is chall

150 ded by sensitively adjusting their shapes in three dimensions ('biocryomorphic evolution') thus maint

151 X-ray topography can image dislocations in three dimensions, but with reduced resolution.

152 ocesses, we image the impalement dynamics in three dimensions by confocal microscopy.

153 rophobic moment of a molecule as a vector in three dimensions by evaluating the surface distribution

154 confinement can be gradually relaxed in all three dimensions by growing epitaxial CdS layers on both

155 ructure and actuate hydrated gels in two and three dimensions by locally patterning ions via their di

156 We validated full organ reconstruction in three dimensions by reconstructing the well-characterize

157 n plunge-frozen form, can be investigated in three dimensions by scanning electron microscopy imaging

158 tics of FcgammaRIII isoforms are obtained in three dimensions by surface plasmon resonance and in two

159 nhance spatial resolution (to <300 nm in all three dimensions) by applying our method to single-view

160 al correlations of neurovascular coupling in three dimensions, by applying a single 10 ms pulse of li

161 If applied in three dimensions, CDI can thus recover the sample's elec

162 thod improves up to an order of magnitude in three dimensions compared to conventional tracking metho

163 actin filaments as semiflexible polymers in three dimensions composed of beads connected with spring

164 interactions are further characterized with three-dimension cultures, in which P3 regenerative cells

165 fine and classify activity cliffs in two and three dimensions, data mining investigations to systemat

166 atter show a linear electronic dispersion in three dimensions described by two copies of the Weyl equ

167 topological superconductors in both two and three dimensions display SUSY when probed at long distan

168 ate these processes non-destructively and in three-dimensions during the sintering of a simple copper

169 struction microscopy (STORM) techniques into three dimensions, effective localization depths do not t

170 angled carbon nanotube (CNT) networks in all three dimensions, employing the CNTs in their high tensi

171 We extended previous efforts in three dimensions, examining a more comprehensive set of

172 When cultured in three dimensions, FL cells display resistance to doxorub

173 Measurement of three dimensions followed by calculation of resultant vo

174 ossibility of detailed flux visualization in three dimensions for many physicochemical processes.

175 rtant role in unveiling atomic behaviours in three dimensions for nanomaterials during various fundam

176 of distortions and can be readily warped in three dimensions, for example, for comparing multiple an

177 structure of binary nanoparticle mixtures in three dimensions from self-assembly opens enormous oppor

178 ative to their neighbors, two dimensions and three dimensions have similar behavior as the glass tran

179 conservation exhibit low overlap across the three dimensions, highlighting the need for an integrati

180 many of which exhibit elaborate curvature in three dimensions, illustrated for example by orchid flow

181 s, as well as Ebola virus-like particles, in three dimensions in a near-native state.

182 rom the Mesozoic Era, which are preserved in three dimensions in a specimen from the Late Cretaceous

183 es with an SprB antibody and tracked them in three dimensions in an evanescent field where the nanopa

184 ed laser to create defined fiducial marks in three dimensions in fixed tissue.

185 complex in invading endothelial cultures in three dimensions in response to stimulation by sphingosi

186 However, analyzing such processes in three dimensions in vivo is challenging.

187 aceous gland and its associated disorders in three dimensions in vivo.

188 ce of Turing patterns that can exist only in three dimensions, including curved surfaces, hexagonally

189 hology and molecular diffusion parameters in three dimensions independently of the imaging depth.

190 the hippocampus can be differentiated along three dimensions (input divergence, transmitter mobiliza

191 How DNA is organized in three dimensions inside the cell nucleus and how this af

192 how to reconstitute MPs coherently in two or three dimensions into non-lipid-based artificial membran

193 ven though real-world motion often occurs in three dimensions, involving a change in distance from th

194 arch problem by the predator for its prey in three dimensions is a difficult problem: it requires the

195 As the extension to three dimensions is accompanied by a considerable dose a

196 ed structures within large intact tissues in three dimensions is an area of intense focus.

197 The characterization in three dimensions is enabled by acquisition and analysis

198 of imaging strain on the nanometer scale in three dimensions is highly novel.

199 Moreover, tracking and imaging in three dimensions is made possible by various techniques,

200 that E. coli bacterial chromosome folding in three dimensions is not dictated entirely by genetic pos

201 f medical devices, the study of the heart in three dimensions is particularly useful to understand it

202 delocalisation of mobile electrons in two or three dimensions is probably one of the key aspects that

203 g their available structural features in all three dimensions is still a challenging task.

204 How these cells operate in three dimensions is unknown, even though the real world

205 hic microstructure, non-destructively and in three-dimensions, is a powerful tool for understanding m

206 s already been theoretically extrapolated to three dimensions, it usually still remains restricted to

207 dependently of system preparation in two and three dimensions, leading to kappa approximately 1.41, a

208 Isolated cells can be cultured (in two or three dimensions), manipulated by lentiviral transductio

209 Xist coats the X chromosome by searching in three dimensions, modifying chromosome structure, and sp

210 g prospect is the printing and patterning in three dimensions of all the components that make up a ti

211 synaptic architecture at high resolution in three dimensions of an intact vertebrate in a close-to-n

212 We assessed three dimensions of auditory spatial function: externali

213 The three dimensions of climate change vulnerability are as

214 s (do, re, mi, etc.) are associated with the three dimensions of color (hue, saturation, and value/br

215 x framework, we assess their progress across three dimensions of coverage: who, what services, and wh

216 n) which, after rotation, were identified as three dimensions of empowerment: attitude to violence, s

217 rrently protected areas poorly represent the three dimensions of mammalian biodiversity.

218 ubstantively important causal effects on all three dimensions of persuasion but no such effects on is

219 nalyses the road to universal coverage along three dimensions of protection: against health risks, fo

220 nvestigated this possibility by relating the three dimensions of reward to an old, robust and extensi

221 ions where metabolism predicted variation in three dimensions of the AT phenotype: hypothalamic-pitui

222 citation provides high spatial resolution in three dimensions of the corresponding chemical or physic

223 stinguished brain regions that predicted all three dimensions of the phenotype from those that select

224 arly modest differences were observed in all three dimensions of the work engagement construct.

225 Two of the three dimensions of this index are based on gross domest

226 r chains that are programmably positioned in three dimensions on a DNA core and display increased nuc

227 scopy (STORM), which provides information in three dimensions on large cellular volumes at 70 nm reso

228 e, we develop mathematical models in two and three dimensions on longer timescales that recapitulate

229 We characterize their geometric structure in three dimensions on the basis of experimental conductanc

230 ationships (SARs) can be further explored in three dimensions on the basis of the corresponding 3D-cl

231 is arrangement the ablation plume expands in three dimensions, only a small portion of it is ionized

232 reward learning task where options varied on three dimensions, only one of which predicted reward.

233 ently, such techniques have been extended to three dimensions, opening up unprecedented possibilities

234 e exists no method to describe structures in three dimensions or molecules with irregular shape.

235 gation of a nontrivial surface wave across a three-dimension physical step.

236 oteins and epigenetic marks are organized in three dimensions remains unknown.

237 Expansion of these mutant dendrites in three dimensions results in overlap of dendritic fields.

238 of nanoparticles on the cellular contour in three dimensions revealed long-range deceleration of the

239 average over many concepts and domains these three dimensions (reward, risk, and uncertainty) should

240 The Brownian motion of two particles in three dimensions serves as a model for predicting the di

241 can persuade their constituents directly on three dimensions: substantive attitudes regarding policy

242 even for species that can move freely in all three dimensions, such as birds and fish.

243 scuss the methodology, which is comprised of three dimensions: supply risk, environmental implication

244 to build large-scale microfluidic systems in three dimensions that are modular, diverse, and predicta

245 We track simultaneously and in three dimensions the motion of flow tracers and plankton

246 DI; refs 11, 12) can be used to visualize in three dimensions, the entire network of dislocations pre

247 has been made towards free-space cloaking in three dimensions, the material properties required are i

248 As surface growth is tracked in three dimensions, the method is applicable to young leav

249 also predict optimal organization in one and three dimensions, the number of modules, and, with added

250 In three dimensions, the opening in the BM was found to inc

251 ng, these structures can also be resolved in three dimensions to a depth of 800 nm.

252 d sequence that are verified structurally in three dimensions to be high fidelity by single-particle

253 al research has moved toward cell culture in three dimensions to better recapitulate native cellular

254 up a tissue (cells and matrix materials) in three dimensions to generate structures similar to tissu

255 of cellulose Ibeta periodically repeated in three dimensions to mimic the solid cellulose.

256 ration by reducing the orientation task from three dimensions to one.

257 the design of proteins that self-assemble in three dimensions to yield macroscopic crystals.

258 ining these techniques and extending them to three dimensions, to produce scanning precession electro

259 re seed sizes, to model the seed interior in three dimensions, to quantify the lipid content, and to

260 Soft robotic tentacles that move in three dimensions upon pressurization are fabricated by c

261 n this study, we explored dynein motility in three dimensions using an MT bridge assay.

262 We studied normal fission in tissue in three dimensions using high-resolution imaging and used

263 Purkinje fiber network, which was imaged in three dimensions using optical projection tomography.

264 noparticles inside whole eukaryotic cells in three dimensions using scanning transmission electron mi

265 ith a solar reconnection event is studied in three dimensions using the combined perspectives of two

266 Here we show detailed upwelling pathways in three dimensions, using hydrographic observations and pa

267 hemical transformations were investigated in three dimensions, using state-of-the-art X-ray energy-di

268 n numerical solutions of Stokes equations in three dimensions, validated with experiments reported in

269 esin and carbon fiber fluid to be aligned in three dimensions via controlled micro-extrusion and subs

270 by spectral confirmation via DF-HSI, and in three dimensions via nano-CT.

271 Using high-resolution imaging in two and three dimensions, we demonstrated that postnatal mouse m

272 eviously predicted nitrate concentrations in three dimensions were themselves predictive of arsenic a

273 The latter might therefore be crucial in three dimensions where frictional forces are likely to b

274 This is a prototypical system in three dimensions where frustration arises from competing

275 ire serial measurements of primary tumors in three dimensions, whereas the Response Evaluation Criter

276 ructural specificities of RBP targets in all three dimensions, which can be further used to predict n

277 that guide crack propagation and twisting in three dimensions, which we have followed using an origin

278 a particle to have linear dispersion in all three dimensions while being doubly degenerate at a sing

279 atures of multiple cell type interactions in three-dimensions while allowing tight control of the mic

280 f partially coherent diffraction patterns in three dimensions, while simultaneously determining the c

281 the aforementioned features are evaluated in three dimensions, while the degradation of the zeolite f

282 ular resolution and millisecond precision in three dimensions will accelerate the pace of neuroscienc

283 espond to filled 1S and 1P shells in two and three dimensions with a valence of 2 for V, whereas the

284 yzing bacterial swarming behavior in two and three dimensions with both high-resolution and wide-spat

285 eveals the internal structure of synapses in three dimensions with exceptional spatial resolution.

286 , it is a challenge to localize molecules in three dimensions with high precision in such samples whi

287 lution and fidelity architectures in two and three dimensions with line widths down to 1 mum are form

288 High-resolution features in two and three dimensions with line widths down to one micrometer

289 c tomography--to probe optical properties in three dimensions with nanometre-scale spatial and spectr

290 opy (TEM) can now visualize strain fields in three dimensions with near-atomic resolution.

291 gardens are mineral aggregates that grow in three dimensions with plant-like forms and share propert

292 lex phenotypes are automatically captured in three dimensions with unprecedented speed and detail in

293 scribe a method to code complex materials in three-dimensions with tunable structural, morphological

294 ime evolution of the F-actin distribution in three dimensions, with branching included as a direction

295 Our model extends easily to three dimensions, with either one converging and two ext

296 provides subnanometre spatial resolution in three dimensions, with single electron-spin sensitivity.

297 ce in rating scales is accounted for by just three dimensions, with these dimensions being Evaluation

298 These probes can be manipulated in three dimensions within a standard microscope to target

299 ar S. aureus and to localize them exactly in three dimensions within endothelial cells.

300 z scan rates over hundreds of microns in all three dimensions without introducing aberration.