ライフサイエンスコーパス: colloidal particle

1 olymer interface in densely polymer-tethered colloidal particles.

2 ining dense amorphous packings of core-shell colloidal particles.

3 rd guiding interactions of biomolecules with colloidal particles.

4 he binding selectivity of cargo-transporting colloidal particles.

5 olled nanoparticle assemblies in the form of colloidal particles.

6 ing aqueous solubility profiles in composite colloidal particles.

7 l double layer compression, similar to other colloidal particles.

8 in a suspension of synthetic photoactivated colloidal particles.

9 the entrapment in the biopolymeric matrix of colloidal particles.

10 s are nanoparticle assemblies in the form of colloidal particles.

11 y using robust diamond-coated spheres, i.e., colloidal particles.

12 tioning and thus enrichment of C(60)O in the colloidal particles.

13 repulsion that stabilizes bulk assemblies of colloidal particles.

14 ers, bimetallic nanorods, as well as passive colloidal particles.

15 entrifugation to shape-separate a mixture of colloidal particles.

16 lastic properties on the scale of individual colloidal particles.

17 tical sizing and mass density measurement of colloidal particles.

18 the control of specific DNA linkages between colloidal particles.

19 ectrochemical properties of alabandite (MnS) colloidal particles.

20 ectral region due to the periodic spacing of colloidal particles.

21 intracellular delivery of proteins and small colloidal particles.

22 ly suggests an analogy to the aggregation of colloidal particles.

23 of monodisperse, highly charged polystyrene colloidal particles.

24 tion somewhat like the Brownian movements of colloidal particles.

25 g such structures is through the assembly of colloidal particles.

26 n of anisotropic chainlike structures by the colloidal particles.

27 ent with sequestration of the protein on the colloidal particles.

28 perties of both liquid crystal molecules and colloidal particles.

29 urface-active agents such as surfactants and colloidal particles.

30 mission has been achieved in nanometer-scale colloidal particles.

31 f diffusion-limited aggregation of nonliving colloidal particles.

32 iquid and a gas stabilized by surface-active colloidal particles.

33 ng the nonlinear electrophoretic mobility of colloidal particles.

34 sting of long flexible polymers grafted onto colloidal particles.

35 out-of-equilibrium dynamic assembly of these colloidal particles.

36 s that are driven by changes in the shape of colloidal particles.

37 y for shape control of anisotropic polymeric colloidal particles.

38 es a new method for the directed assembly of colloidal particles.

39 deformation of a lipid membrane by adhering colloidal particles.

40 f the effective electrostatic forces between colloidal particles.

41 ding free DNA strands and DNA-functionalized colloidal particles.

42 a condensed matter analog, a 2D ensemble of colloidal particles.

43 l science, where the main goal is to develop colloidal particles(2,3) that mimic and exceed the diver

44 application of a coupled resonance model for colloidal particle adhesion in a liquid phase theoretica

45 dynamically tune an assembly of anisotropic colloidal particles adsorbed at fluid-fluid interfaces u

46 Paramagnetic colloidal particles aggregate into linear chains under a

47 ribution around a pair of such heated/cooled colloidal particles agrees quantitatively with the theor

48 olarized optical microscopy that anisotropic colloidal particles align perpendicular to the flow dire

49 At equilibrium, colloidal particles always gather at the bottom of any a

50 y diffusing in all directions, they resemble colloidal particles and atoms, self-assembling into crys

51 he non-invasive trapping and manipulation of colloidal particles and biological cells(1,2).

52 developed to study the ionic interaction of colloidal particles and biopolymer molecules on a microa

53 , detection, and treatment, as well as novel colloidal particles and building blocks for mutlifunctio

54 Using a variety of colloidal particles and commercial polymers, ionic collo

55 ss made in the synthesis of nanocrystals and colloidal particles and draw analogies between these new

56 de a minimally invasive means for delivering colloidal particles and engineered red blood cells acros

57 itions, as demonstrated in recent studies of colloidal particles and glass-forming metallic systems.

58 ickering emulsions over typical micron-sized colloidal particles and ligand-stabilized nanoparticle s

59 ent, separation mechanism for mum and submum colloidal particles and organelles, taking advantage of

60 Here we demonstrate manipulation of colloidal particles and self-assembled structures in nem

61 ability to manipulate small fluid droplets, colloidal particles and single cells with the precision

62 e interrelation between surface chemistry of colloidal particles and surface adsorption of biomolecul

63 se of attractive Coulomb interaction between colloidal particles and surfactant structures offers a p

64 veins, namely, the transport of the gold as colloidal particles and their flocculation in nanoscale

65 phages as microbial tracer for transport of colloidal particles and water flow.

66 thesis of the support in the presence of the colloidal particles, and (iii) direct impregnation of th

67 tags may be used to organize the assembly of colloidal particles, and DNA templates can direct the gr

68 ical composition, size and polydispersity of colloidal particles, and many methods have been develope

69 es with payloads, into stable suspensions of colloidal particles, and the different means for trigger

70 The colors of suspended metallic colloidal particles are determined by their size-depende

71 sma resonance, while those of semiconducting colloidal particles are determined by their size-depende

72 Nanoscale or colloidal particles are important in many realms of scie

73 "Coffee rings" of spherical colloidal particles are left behind after water droplets

74 Synthetic patchy colloidal particles are often poor geometric approximati

75 where the sodium borohydride-reduced silver colloidal particles are present, Stokes spectra collecte

76 ause the (111) planes of the fcc polystyrene colloidal particle array have an approximately 200-nm la

77 ), colloidal crystal templating (3-D ordered colloidal particles as a template), and super lattice ro

78 The newly formed interface sequesters the colloidal particles; as the interface coarsens, the part

79 It highlights aspects of the choice of colloidal particles, assembly of the colloidal crystal t

80 roughput method can yield surface-structured colloidal particles at a rate of approximately 10(7) to

81 surements of attractive interactions between colloidal particles at an oil-water interface and show t

82 r, we exploit capillary interactions between colloidal particles at liquid interfaces to create two-d

83 resent an experimental realization of patchy colloidal particles based on material independent deplet

84 py, respectively, reveal that 1-microm-sized colloidal particles bearing nuclear transport receptors

85 be the aggregation effects of semiconducting colloidal particles but also fundamental insights into t

86 Of these, 17 formed colloidal particles by dynamic light scattering and exhi

87 roach to the synthesis of asymmetric, hybrid colloidal particles by precipitation polymerization.

88 opole-to-quadrupole reconfiguration of these colloidal particles by unstructured light, which resembl

89 We find that a single 2-mum colloidal particle can bind to 40 different types of par

90 e diffusion rates of a wide range of natural colloidal particles can be predicted from theory, so lon

91 on reports that needle-like supercrystalline colloidal particles can be synthesized through anisotrop

92 Colloidal particles can form unexpected two-dimensional

93 mechanisms by which globular macromolecules (colloidal particles) can cause polymer-coated nanopores

94 of negatively charged surfaces (for example, colloidal particles) can spontaneously partition into an

95 microcapsules with shells of densely packed colloidal particles closer to application in fields such

96 picture describing their behavior is that of colloidal particles; colloids exhibit a sharp increase i

97 Liposomes are colloidal particles composed of spontaneously forming li

98 l methods to investigate the transition of a colloidal particle confined in an optical trap between t

99 sis and functionalization of nanometer-sized colloidal particles consisting of well-defined, water-so

100 ents, such as biological cells and synthetic colloidal particles, consume internal energy or extract

101 has been proposed that complex nonspherical colloidal particles could act as "colloidal molecules" i

102 Such composite colloidal particles could potentially serve as an approa

103 Colloidal particles covered with chemically-active patch

104 n based formation of colloidal capsules, the colloidal particle deposition on (sacrificial) templates

105 rmed by the disclination loops that entangle colloidal particles dispersed in a nematic liquid crysta

106 Colloidal particles dispersed in liquid crystals can for

107 s can be patterned by tuning the topology of colloidal particles dispersed in them.

108 of a theoretical phase diagram obtained for colloidal particles displaying short-range attractive in

109 Colloidal particles disturb the alignment of rod-like mo

110 wever, in other respects, the nonequilibrium colloidal particles do not behave as monopoles: They can

111 nclude the hydrodynamic interactions between colloidal particles driven in viscous fluids, phoretic i

112 targets for the programmed self-assembly of colloidal particles, due to their applications as photon

113 ommonly used to study interactions of single colloidal particles, e.g., on biological samples like li

114 Nanostructured materials based on colloidal particles embedded in a polymer network are us

115 Colloidal particles endowed with specific time-dependent

116 present a multivalent model system based on colloidal particles equipped with surface-mobile DNA lin

117 Colloidal particles equipped with two, three, or four ne

118 ave been developed to direct the assembly of colloidal particles, fabrication of crack-free and trans

119 ate the potential of these superparamagnetic colloidal particles for high-throughput analysis of glyc

120 ss of materials, namely colloidosomes (using colloidal particles for Pickering stabilization and fusi

121 have since exploited the Brownian motion of colloidal particles for studies of dissipative processes

122 Utilizing colloidal particles for the assembly of the shell of nan

123 scillatory micromotor system in which active colloidal particles form clusters, the size of which cha

124 ped to trap, manipulate, assemble, and print colloidal particles from aqueous solutions into desired

125 ame size fraction-possibly due to release of colloidal particles from LSL corrosion scale enriched wi

126 Spherical colloidal particles generally self-assemble into hexagon

127 In conventional research, colloidal particles grafted with single-stranded DNA are

128 With increasing size of the constituent colloidal particles, grating diffraction effects dominat

129 In addition, all prepared astaxanthin colloidal particles had significantly (p<0.05) higher ce

130 ew mechanism for regulating the stability of colloidal particles has been discovered.

131 Interest in assemblies of colloidal particles has long been motivated by their app

132 res from primary building blocks (molecules, colloidal particles) has made remarkable progress over t

133 stabilized by lipid interfacial bilayers or colloidal particles have been extensively investigated i

134 The individual colloidal particles have interfacial attachment energies

135 Artificial self-propelled colloidal particles have recently served as effective bu

136 Colloidal particles have the right size to form ordered

137 ry colloids, which consist of different size colloidal particles, have the potential to achieve high

138 dynamic and optical scattering properties of colloidal particles having nonspherical morphologies.

139 bined with Maxwell's equations, suggest that colloidal particles heated or cooled in certain polar or

140 Colloidal particles immersed in liquid crystals frustrat

141 Our system is a micron-scale colloidal particle in water, in a virtual double-well po

142 sotropic electrostatic screening for charged colloidal particles in a nematic electrolyte.

143 Charged dumpling-shaped near-spherical colloidal particles in a nematic medium are used as an e

144 rected net diffusional flux of molecules and colloidal particles in a temperature gradient.

145 BCC) crystals and their liquid using charged colloidal particles in an electric bottle.

146 Dispersions of colloidal particles in cholesteric liquid crystals form

147 jums may lead to controlled self-assembly of colloidal particles in nematic and paranematic hosts, wh

148 m cations used in the reductive synthesis of colloidal particles in solution at room temperature.

149 the advantage of entrapping quercetin in the colloidal particles in terms of the chemical stability i

150 Self-assembling colloidal particles in the cubic diamond crystal structu

151 ation gradient to drive autonomous motion of colloidal particles in the highly confined space, and th

152 Colloidal particles in the nanometre size range (less th

153 ported, obtained by frothing a suspension of colloidal particles in the presence of a small amount of

154 The colloidal particles in the self-assembled cubic diamond

155 Dispersion of colloidal particles in water or oil is extensively desir

156 Sorting of colloidal particles, including protein complexes, cells,

157 instant assembly of superparamagnetic (SPM) colloidal particles inside emulsion droplets of UV curab

158 Here, the silica colloidal particles interact with each other and the por

159 How colloidal particles interact with each other is one of t

160 erms of a classical model of the kinetics of colloidal particle interactions in solution.

161 We show that chirality of colloidal particles interacts with the nematic elasticit

162 de surface, contribute to focus the incoming colloidal particles into a thin beam.

163 Self-assembly of colloidal particles into colloidal films has many actual

164 Control of the assembly of colloidal particles into discrete or higher-dimensional

165 guide the self-assembly of micrometer-sized colloidal particles into fully programmable crystal stru

166 Constructing colloidal particles into functional nanostructures, mate

167 at is capable of organizing a diverse set of colloidal particles into highly reproducible, rotational

168 the sole mechanism that enables transport of colloidal particles into or out of the channels, but it

169 Self-assembly of colloidal particles into ordered superstructures enables

170 Self-assembly of colloidal particles into ordered superstructures is an i

171 The dynamical arrest of attractive colloidal particles into out-of-equilibrium structures,

172 We demonstrate that the transport of colloidal particles into the dead-end channels can be ei

173 The self-organization of colloidal particles is a promising approach to create no

174 Attraction between colloidal particles is believed to lead to particle aggr

175 he monopole-like fields around heated/cooled colloidal particles is crucial because the experimental

176 A periodic array of colloidal particles is embedded in a hydrogel network wi

177 laminar shear flow, the diffusion of passive colloidal particles is enhanced in the direction paralle

178 d transition in a 2D crystal of paramagnetic colloidal particles is induced by a magnetic field [Form

179 d assemble three-dimensional structures from colloidal particles is limited by the absence of specifi

180 The presence of amorphous colloidal particles is ubiquitous in many zeolite synthe

181 The large-scale assembly of asymmetric colloidal particles is used in creating high-performance

182 substances--in particular macromolecules and colloidal particles--is a canonical problem limiting adv

183 We introduce a method for transporting colloidal particles, large molecules, cells, and other m

184 The incorporation of colourants in colloidal particles led to the generation of different s

185 putum greatly reduces the diffusion rates of colloidal particles, limiting the effectiveness of gene

186 During the charging process, the SiO(2) colloidal particles located at the carbon felt interface

187 Stable colloidal particles (<350 nm) containing drug, polyvinyl

188 omimetic, self-templating assembly of chiral colloidal particles (M13 phage) into functional material

189 y the method proposed here to real data from colloidal particles, microgels, and polymer solutions.

190 Immersed colloidal particles modify the fluid's ordered molecular

191 In contrast to molecular and hard colloidal particle monolayers, the single layers tend to

192 erated by the dissociation of carbonic acid, colloidal particles move either away from or towards the

193 For an overdamped, Brownian colloidal particle moving in a tilted double-well potent

194 important intrinsic property of noble metal colloidal particles, namely, plasmonic resonance.

195 nge electrostatic repulsions between charged colloidal particles occur in these solvents.

196 This method separates colloidal particles of comparable density by mass.

197 trands is "stamped" from a gold surface onto colloidal particles of different sizes by streptavidin-b

198 Colloidal particles of metals and semiconductors have po

199 Colloidal particles of suitable wettability adsorb stron

200 constituted the two-dimensional diffusion of colloidal particles on a molecular brush surface.

201 ation and dynamic patterning of a variety of colloidal particles on a solid substrate at nanoscale ac

202 Assembly of colloidal particles on fluid interfaces is a promising t

203 teraction, which enables the manipulation of colloidal particles on solid substrates with optical sca

204 In this paper, immobilization of gold colloidal particles onto amine-modified magnetic micropa

205 sules are fabricated by the self-assembly of colloidal particles onto the interface of emulsion dropl

206 wnian dynamics of individual tracers such as colloidal particles or lipid domains have provided insig

207 Colloidal particles or nanoparticles, with equal affinit

208 onstituents such as the interactions between colloidal particles, or the enzymatic behaviour of de no

209 The number of colloidal particles (per unit area) on the mica surfaces

210 Emulsion droplets stabilised by colloidal particles (Pickering emulsions) can be highly

211 ourants respectively and incorporated in the colloidal particles prepared from food protein-zein.

212 The colloidal particles preserved a high degree of halogen c

213 consequence of reduced crystallinity of the colloidal particles, presumably due to the different coo

214 sible classes of inorganic species and their colloidal particle properties in the precursor solutions

215 Patches on the surfaces of colloidal particles provide directional information that

216 pt of a jamming phase diagram for attractive colloidal particles, providing a unifying link between t

217 knotted nematic disclinations stabilized by colloidal particles raised a challenge of free-standing

218 nt evaporation, non-interacting monodisperse colloidal particles self-assemble into a close-packed su

219 The dynamic manipulation of colloidal particle shape offers a novel design mechanism

220 serted interstitials in a lattice of similar colloidal particles sitting on flat or curved oil/glycer

221 In addition, neutralization kept a stable colloidal particle size for pHs decreased to pH 9,8 and

222 lization created casein aggregates of larger colloidal particle size than primary casein micelle in c

223 s) and sorting by refractive index (of other colloidal particle streams).

224 Colloidal particles subject to an external periodic forc

225 lf-spinning objects such as chiral grains or colloidal particles subject to torques.

226 heterotypic aggregation of cell mixtures or colloidal particles such as proteins occurs in a variety

227 sional reduced graphene oxide structures and colloidal particles, such as trefoil knots, with 'frozen

228 nating current (ac) electrokinetic motion of colloidal particles suspended in an aqueous medium and s

229 nk contains bubbles stabilized by attractive colloidal particles suspended in an aqueous solution.

230 is framework to the study of the dynamics of colloidal particle suspensions for packing fractions cor

231 reproduced by either biopolymer networks or colloidal particle systems alone.

232 Research on Janus and colloidal particles that are chemically patchy in even m

233 o immiscible liquids, kinetically trapped by colloidal particles that are irreversibly bound to the o

234 quid crystalline behavior can be probed with colloidal particles that are macro-aggregates of biomole

235 ed nematic layers stabilized by 2D arrays of colloidal particles that can be controlled with laser tw

236 ed on a controlled deformation of multiphase colloidal particles that can be selectively liquified, p

237 r strategy uses motors in the form of active colloidal particles that constantly propel forward.

238 dra, which are simple models for anisotropic colloidal particles that form a quasicrystal.

239 f boojums by controlling surface topology of colloidal particles that impose tangential boundary cond

240 poly(N-isopropylacrylamide) (PNIPAM) nanogel colloidal particles that self-assemble into crystalline

241 h GO sheet is a single molecule as well as a colloidal particle, the molecule-colloid duality makes i

242 Diffusiophoresis is the migration of a colloidal particle through a viscous fluid, caused by a

243 tion can be overcome by targeted delivery of colloidal particles through hydrodynamic flows.

244 Adsorption to colloidal particles thus provides an attractive route fo

245 pect ratio of the asymmetric block copolymer colloidal particles to be correlated with the experiment

246 : during the deposition process, this causes colloidal particles to be swept from darkened areas into

247 LCA) to a multicomponent system of spherical colloidal particles to enable the rational design and pr

248 or applications ranging from the assembly of colloidal particles to enrichment of rare cells.

249 F) particles have been proposed as promising colloidal particles to form ordered superstructures, bas

250 Here, we use shape anisotropy of colloidal particles to introduce chiral rollers with act

251 hat both models predict selective binding of colloidal particles to large target molecules on the sur

252 o diverse nucleation scenarios, ranging from colloidal particles to natural gas hydrates, and that, a

253 apillarity can be used to direct anisotropic colloidal particles to precise locations and to orient t

254 ed nematic liquid crystals (LCs) to assemble colloidal particles trapped at the LC interface into rec

255 An optical binding force between two nearby colloidal particles trapped by two coherent laser beams

256 Even in the simple case of hard-sphere colloidal particles under shear, there are conflicting p

257 neering thin magnetic films onto homogeneous colloidal particles, various crystalline lattices are in

258 ) pascals, containing high concentrations of colloidal particles (volume fraction phi greater, simila

259 When an aqueous dispersion of colloidal particles was allowed to dewet from a solid su

260 The spherical shape of the colloidal particles was confirmed using transmission ele

261 ntropic ordering characteristics of athermal colloidal particles, we demonstrate that high-symmetry n

262 conjunction with the structural rigidity of colloidal particles, we demonstrate the parallel self-as

263 Next, the colloidal particles were dispersed onto high-surface-are

264 d residual solvent concentration of prepared colloidal particles were evaluated.

265 Electrophoretically deposited colloidal particles were observed to move toward one ano

266 Quercetin loaded biopolymeric colloidal particles were prepared by precipitating querc

267 Astaxanthin colloidal particles were produced using solvent-diffusio

268 Here we show that deformable colloidal particles, when studied through their concentr

269 Specifically, we consider colloidal particles which are polygonal plates with homo

270 tudy the motion of asymmetric self-propelled colloidal particles which have a homogeneous mass densit

271 re solvent to be absorbed into the polymeric colloidal particle, which, in turn, lowers the glass tra

272 unexpected, charge-dependent accumulation of colloidal particles, which occurs in a common-flow confi

273 curs via the flocculation of semicrystalline colloidal particles, which results in the gels exhibitin

274 uid-to-solid transition of weakly attractive colloidal particles, which undergo markedly similar gela

275 s into 'flocs' and destabilizes and enmeshes colloidal particles while the core is exposed to water,

276 ants, and these typically bound tighter to a colloidal particle, while the only mutant it stabilized

277 non-aqueous suspension of 'sticky' polymeric colloidal particles with a controlled degree of polymeri

278 Colloidal particles with a repulsive interparticle poten

279 s colloidal spheres as keys and monodisperse colloidal particles with a spherical cavity as locks tha

280 nucleation clusters and produces much larger colloidal particles with accelerated nucleation.

281 e colloidal analogues of atoms with valence: colloidal particles with chemically distinct surface pat

282 Patterning of colloidal particles with chemically or topographically d

283 Here we fabricate and study colloidal particles with different numbers of handles an

284 Colloidal particles with directional interactions are ke

285 scalable bulk synthesis of customized chiral colloidal particles with geometric and compositional chi

286 Colloidal particles with hollow interiors play important

287 ely 10(8)) of both non-magnetic and magnetic colloidal particles with micrometre precision and typica

288 rface active compounds lead to production of colloidal particles with more desirable physicochemical

289 methods offer scalable means of synthesizing colloidal particles with precisely specified size for ap

290 ructures of controlled size and shape out of colloidal particles with short-ranged interactions.

291 Colloidal particles with site-specific directional inter

292 S20, SC and GA could produce the astaxanthin colloidal particles with small particle size, polydisper

293 Colloidal particles with strongly attractive interaction

294 iffusiophoresis enables robust patterning of colloidal particles with substantially finer length scal

295 Mesoporous colloidal particles with tailored asymmetric morphologie

296 We develop model "banana-shaped" colloidal particles with tunable dimensions and curvatur

297 to create ordered arrays of micrometre-sized colloidal particles with tunable patterns.

298 Colloidal particles with well-controlled shapes and inte

299 relies upon the spatial organization of the colloidal particles within the polymer network that depe

300 merical determination of forces between such colloidal particles would be complicated by the presence