ライフサイエンスコーパス: Brownian motion

1 resulting in a gradual decrease in the bead Brownian motion.

2 erm vanishes and strong chaos again leads to Brownian motion.

3 se obtained with space-dependent slowed-down Brownian motion.

4 via a molecular ratchet mechanism powered by Brownian motion.

5 tion seems random and is often attributed to brownian motion.

6 of micrometer-sized COM crystals capable of Brownian motion.

7 gning functional nanosystems based on random Brownian motion.

8 nvironment rather than transport by a random Brownian motion.

9 a simple stochastic model based on geometric Brownian motion.

10 of the cell from the solid surface caused by Brownian motion.

11 ics, van der Waals force, hydrodynamics, and Brownian motion.

12 sis, electrophoresis, ac-electroosmosis, and Brownian motion.

13 lecules in solution by direct suppression of Brownian motion.

14 developed within the framework of rectified Brownian motion.

15 n for a stochastic process beyond fractional Brownian motion.

16 of fluctuations in bead force as a result of Brownian motion.

17 e the competition between viral lability and Brownian motion.

18 revealed that chromatin undergoes extensive Brownian motion.

19 rements with single molecules are evident as Brownian motion.

20 shapes have the largest random dispersal by Brownian motion.

21 is limited by rotational diffusion caused by Brownian motion.

22 -scale movements is hindered by superimposed brownian motion.

23 based on Monte Carlo simulations of confined Brownian motion.

24 les and are well-suited for investigation of Brownian motion.

25 the cancer site more quickly than by simple Brownian motion.

26 potential disorder on the track, and against Brownian motion.

27 trophils show pure superdiffusive fractional Brownian motion.

28 ends a random version of Bertrand model with Brownian motion.

29 objects are stochastically displaced due to Brownian motion.

30 ng fundamentally different from conventional Brownian motion.

31 ng or rising effects, rather than stochastic Brownian motion.

32 destabilizing effect of scattering force and Brownian motion.

33 ble to pass through a mucus layer by passive Brownian motion.

34 n whether T cell movement is consistent with Brownian motion.

35 bling of escape rates compared to unhindered Brownian motion.

36 port of larger nanomaterials is dominated by Brownian motion.

37 ent is enhanced up to 100% compared to their Brownian motion.

38 n has a profound impact on the near-boundary Brownian motion.

39 markably consistent with those expected from Brownian motion.

40 te to reach active conformations by means of Brownian motions.

41 /-3%) when R(H) is determined by analysis of Brownian motion; 2) the fragments also have the fluoresc

42 ] [8] and may be free to undergo substantial Brownian motion [9].

43 Based on these data, we reject Brownian motion (a random walk) and uniform increasing t

44 are not restrained, they undergo significant Brownian motion, a characteristic traditionally thought

45 Unlike MEs, which exhibit Brownian motion, AEs exhibit directed motion (average, 8

46 ngle MIP inside a solution and analyzing its Brownian motion allow for real-time determination of its

47 Analysing the sphere's Brownian motion allows us to determine the temperature o

48 nge, where conventional NTA methods based on Brownian motion alone would fail.

49 ally) at rates exceeding those expected from Brownian motion alone.

50 he microtubule-dependent kinesin family show Brownian motion along microtubules led us to hypothesize

51 listic) behavior of a polypeptide undergoing Brownian motion along the first few principal components

52 Crucially, the same active Brownian motion also triggers particle splitting, counte

53 creasing size, thereby decreasing particles' Brownian motion amplitude and diffusivity, which can be

54 The mechanical oscillator's Brownian motion, an important source of noise in these m

55 perform up to four and ten times faster than Brownian motion and aGPs, respectively.

56 The fluctuations are modeled by Brownian motion and alpha-stable Levy motion.

57 low a critical shear rate and robust against Brownian motion and cell tumbling.

58 -assembly is mediated by the balance between Brownian motion and cilia-driven flow.

59 Both DNAs exhibit ergodic Brownian motion and comparable mobility reduction in all

60 diffusion type: Brownian motion, fractional Brownian motion and continuous time random walk.

61 GUVs, however, displayed Brownian motion and could not be propelled by attached b

62 the much larger soliton, contributing to its Brownian motion and decreasing its lifetime.

63 sliders on polycationic tracks that exploit Brownian motion and diffusive binding to transport cargo

64 s under the combined effect of laminar flow, Brownian motion and electrophoretic drift, it is shown t

65 Effects of Brownian motion and electrostatic interactions are exclu

66 ffinity of the reaction, locally slowed-down Brownian motion and local hindrance by obstacles both im

67 istribution of interspecies covariance under Brownian motion and Ornstein-Uhlenbeck models of phenoty

68 trained continuous trait evolution using the Brownian motion and Ornstein-Uhlenbeck models, respectiv

69 Gaussian phylogenetic models like Brownian motion and Ornstein-Uhlenbeck processes are the

70 of the zones that only slowly recover due to Brownian motion and particle nucleation.

71 rosecond timescales with dynamics beyond hot Brownian motion and superheated water states persisting

72 recursor movement results predominantly from Brownian motion and that the SecA ATPase regulates pore

73 estimating the Hurst exponent for fractional Brownian motion and the diffusion coefficient for Browni

74 develop a random walk model to simulate the Brownian motion and the electrochemical response of a si

75 , we directly visualize in real-time, the 1D Brownian motion and transcription elongation of T7 RNA p

76 ribution of TE monomer production, increased Brownian motion and variations in scaffold geometry did

77 nts generally suffer from pattern collapses, Brownian motion, and challenges that come with reconfigu

78 ical type of subdiffusive motion, fractional Brownian motion, and its physical analog, generalized La

79 h small particle size was mainly affected by Brownian motion, and its rising was limited; therefore,

80 sliding of the sphere bottom on the surface, Brownian motion, and molecular diffusion.

81 MotI-inhibited flagella rotated freely by Brownian motion, and suppressor mutations in MotA that w

82 sion are considered: obstruction, fractional Brownian motion, and the continuous-time random walk.

83 We use a multiple-variance Brownian motion approach in association with evolutionar

84 he large-distance, long-time asymptotics for Brownian motion are calculated by using a nonlinear stoc

85 Brownian motions are distinctively characterized by a li

86 Although Brownian motion argues that enzymes will eventually bump

87 ntire interval (1, 2) and especially include Brownian motion as the overall most efficient search str

88 The scattering of free BG-AuNP and their Brownian motion as well as BG-AuNP attached on erythrocy

89 the covariances of positions for fractional Brownian motion as well as for exponentially and power-l

90 microorganisms(2), differs considerably from Brownian motion, as revealed by a greatly enhanced diffu

91 myosin, for example, we favor the idea that Brownian motions associated with the flexible converter

92 This highlights the importance of Brownian motions associated with the protein domains tha

93 anoparticle motion is governed by fractional Brownian motion at low dose rates, resembling diffusion

94 third feature, we implemented three methods: Brownian motion, B-splines, and approximate Gaussian pro

95 an be observed indirectly via the drift of a Brownian motion, before optimally filtering the transmis

96 des a supply of particles that aggregate via Brownian motion biased by attractive interparticle poten

97 stoma cell-cell movement can be described as Brownian motion biased by cell-cell potential.

98 Classical Brownian motion (BM), continuous time random walk, and f

99 longitude coordinates-describes spread as a Brownian motion (Brownian Motion Phylogeography, BMP) in

100 ny cellular systems do not exhibit classical Brownian motion but rather anomalous diffusion.

101 membranes is not just simple two-dimensional Brownian motion but typically depends on the timescale o

102 hat chromatin is free to undergo substantial Brownian motion, but that a given chromatin segment is c

103 However, fluctuations due to Brownian motion can make it difficult to precisely resol

104 on-adjacent high concentration region, while Brownian motion can not induce this phenomenon.

105 ion, and the asymmetric barriers rectify the Brownian motion, causing a directional transport of mole

106 The cold Brownian motion (CBM) analysis of individual YLF crystal

107 th dynamics at shorter times is dominated by Brownian motion coalescence (BMC), followed by a growth

108 ive the power spectral density of fractional Brownian motion coexisting with a scale-free continuous

109 Therefore, slowed-down Brownian motion could be considered the macroscopic limi

110 s of magnitude smaller than the force of the Brownian motion destroying the assemblies even for the m

111 somewhat counterintuitively, the diffusional Brownian motion determines the fundamental limitations o

112 entrap two DNAs that come into proximity by Brownian motion (diffusion capture).

113 s revealed that at low field strengths, when Brownian motion dominated the nanoparticle dynamics [Pec

114 to a longitudinal flow exhibit not only the Brownian motion due to diffusion but also the translatio

115 contribution exceeds that due to diffusional Brownian motion during the passage.

116 Owing to Brownian-motion effects, the precise manipulation of ind

117 They also flexed by Brownian motion, exhibiting a persistence length of abou

118 When the frequency spectrum of Brownian motion extends beyond cross-bridge transition r

119 ntinuous, mostly immobile (i.e., no detected Brownian motion) fibrous network that encloses the DNA-d

120 "active baths," traditional concepts such as Brownian motion, fluctuation-dissipation relations, and

121 se findings statistically prove a fractional Brownian motion for the telomere trajectories, which is

122 endent on normal diffusion, driven by random Brownian motion, for host contact.

123 gle-particle trajectories by diffusion type: Brownian motion, fractional Brownian motion and continuo

124 d timescale of 1 mus, unveiling unobstructed Brownian motion from 25 to 100 nm, and partially suppres

125 of moment-generating function and geometric Brownian motion from stochastic mathematics, our analysi

126 The geometric Brownian motion (GBM) is widely used for modeling stocha

127 We found that Brownian motion gives a more adequate description of obs

128 argination and cell interaction, compared to Brownian motion, gravity, and cell membrane deformation

129 Loop extrusion by biased Brownian motion has important implications for chromosom

130 undary dynamics, the effect of interfaces on Brownian motion has remained elusive.

131 ng and counting particles according to their Brownian motion; however, it is limited in sensitivity t

132 e the hydrodynamic instantaneous velocity of Brownian motion in a liquid, which follows a modified en

133 were modeled by a gating particle undergoing Brownian motion in a one-dimensional diffusion landscape

134 They have comparable mobilities and display Brownian motion in extrasynaptic space but are constrain

135 ined the photoelectric effect, and described Brownian motion in five papers, all published in 1905, 1

136 sults shed light on the fundamental roles of Brownian motion in microbial motility, nutrient uptake,

137 has been rigorously tested for directed and Brownian motion in open media.

138 t Levy walks have functional advantages over Brownian motion in random searching and transport kineti

139 birefringence to measure rates of rotational Brownian motion in solution, is not significantly change

140 ounts and sizes particles by measuring their Brownian motion in solution.

141 n(y), t) is obtained for the two-dimensional Brownian motion in the (n(x), n(y)) phase plane.

142 cantly to the rheology or ATP-dependent, non-Brownian motion in the cell interior.

143 ility (mechanical lasing) and the cooling of Brownian motion in the fundamental mode through excitati

144 We show that the underlying Brownian motion in the substrate is the reference elemen

145 ort of particles between two compartments by brownian motion in this way bears similarities to the hy

146 ompressed to high densities while undergoing Brownian motion in two dimensions (2D).

147 The statistics reveal unusual Brownian motion in which the mean square displacement in

148 alizes the shapes and textures of high-order Brownian motions in the microdisks.

149 st artificial molecular motors are driven by Brownian motion, in which, with few exceptions, the gene

150 Brownian motion influences bacterial swimming by randomi

151 NA molecules are visualized while undergoing Brownian motion inside media patterned with molecular-si

152 Near-boundary Brownian motion is a classic hydrodynamic problem of gre

153 Considering that Brownian motion is a self-driven phenomenon, diffusometr

154 Here, we report that the influence of Brownian motion is amplified when it is coupled to hydro

155 l ratchet" in which a thermal fluctuation in Brownian motion is captured by formation of the actomyos

156 the size scale of the polymeric mesh, their Brownian motion is minimally hindered by intermittent co

157 The model of rectified Brownian motion is presented as an alternative to power

158 light, whereas when prey is abundant, simple Brownian motion is sufficiently efficient.

159 However, only in the case of slowed-down Brownian motion is the affinity maximal when the slowdow

160 Brownian motion is widely used as a model of diffusion i

161 This framework, based upon Brownian motion, is analytically tractable and can be us

162 much slower than would be expected from free Brownian motion, is strongly restricted over tens of nan

163 Deviations from Brownian motion leading to anomalous diffusion are found

164 A combination of diffusiophoresis and Brownian motion leads to a strong size-dependent focusin

165 Here we evaluate Brownian motion, Levy walk and several correlated random

166 Inherent Brownian motion limits current force spectroscopy method

167 oses a time-symmetric formulation of quantum Brownian motion, Lindblad and Pauli master equations, wh

168 In such geometries, Brownian motion may be considered as the sole mechanism

169 branes are also heterogeneous media in which Brownian motion may be locally slowed down due to variat

170 Brownian-motion microinterferometry was used to study th

171 logical diversification in Orkney followed a Brownian motion model of evolution, suggesting a primary

172 s of evolution for continuous traits under a Brownian motion model of evolution.

173 In contrast, the Brownian motion model overestimates spatial diffusion ra

174 I simulate random evolution (Brownian motion model) of quantitative characters along

175 y shifts in complexity depart from a uniform Brownian motion model.

176 odels of character evolution, the classical "Brownian motion" model and another model ("Ornstein-Uhle

177 I developed a phylogenetic "diffused Brownian motion" model that characterizes nuanced variat

178 sed on magnetic spectroscopy of nanoparticle Brownian motion (MSB) to quantitatively detect molecular

179 Exploiting the Brownian motion of a levitated nanodiamond, we extract i

180 classical interpretation of FPR data as free Brownian motion of a limited mobile fraction.

181 er, the detection of single photons, and the Brownian motion of a microscopic particle in a fluid are

182 reaction far from equilibrium, can bias the Brownian motion of a particle in an anisotropic medium w

183 The statistical analysis of the Brownian motion of a particle quantifies the viscoelasti

184 ow a polymerizing filament could rectify the Brownian motion of an object so as to produce unidirecti

185 ryotes: localized motion consistent with the Brownian motion of an RNA polymer tethered to its templa

186 mediate filaments significantly restrict the Brownian motion of bacteria.

187 mber of experiments have since exploited the Brownian motion of colloidal particles for studies of di

188 The Brownian motion of domains in a harmonic potential is th

189 ian noise of classic circuits imposed by the Brownian motion of electrons, hence it may have to be mi

190 state to the NPC, and is solely due to rapid Brownian motion of FG-repeats, not FG-repeat hydrophobic

191 ntally by measuring characteristic times for Brownian motion of fluorescent nanospheres through the v

192 otein with dynamics that are governed by the Brownian motion of individual gating blocks.

193 properties of living cells by monitoring the Brownian motion of individual microinjected fluorescent

194 orithm is a lattice-based method that tracks Brownian motion of individual molecules and the stochast

195 We studied the Brownian motion of isolated ellipsoidal particles in wat

196 This result is achieved by random Brownian motion of Lipofectamine-containing vesicles wit

197 ion of biological processes can be driven by Brownian motion of macromolecular complexes with one-sid

198 low observation of dynamic processes such as Brownian motion of mesoscopic particles.

199 We report on the Brownian motion of micrometer-sized beads of glass held

200 oise-limited, high-bandwidth measurements of Brownian motion of micrometer-sized beads suspended in w

201 A with a Brownian ratchet that rectifies the Brownian motion of microscopic particles.

202 The Brownian motion of molecules at thermal equilibrium usua

203 s whose asymmetric disposition rectifies the Brownian motion of molecules driven through the device,

204 The Brownian motion of nanoparticles, confining effect of na

205 e oxide (RGO), we successfully inhibited the Brownian motion of NMO that led to reduced agglomeration

206 on is employed to reveal correlations in the Brownian motion of pairs of fluorescently labeled lipids

207 Brownian motion of particles affects many branches of sc

208 coelastic shear moduli are inferred from the Brownian motion of particles embedded in the cytoskeleta

209 prohibit extraction of useful work from the Brownian motion of particles in equilibrium, these motio

210 al and rotational diffusion characterize the Brownian motion of particles.

211 ntensity of scattered light arising from the Brownian motion of particles.

212 However, collective Brownian motion of phase-separated domains and compositi

213 the effect of intermolecular interactions on Brownian motion of proteins, we performed (1)H pulsed-fi

214 thering, we have tracked the nanometer-scale Brownian motion of RNA-tethered fluorescent microspheres

215 reement with theoretical predictions for the Brownian motion of rods.

216 Here we present a technique that uses Brownian motion of single molecules to probe the local f

217 d relaxed circular molecules by tracking the Brownian motion of single molecules with fluorescence mi

218 y 6 to 290 kbp were measured by tracking the Brownian motion of single molecules.

219 ian Electrokinetic (ABEL) trap to counteract Brownian motion of single particles in real time, we dir

220 We observed and controlled the Brownian motion of solitons.

221 on a surface is achieved by using the biased brownian motion of stimuli-responsive rotaxanes ('molecu

222 Measurement of the instantaneous velocity of Brownian motion of suspended particles in liquid probes

223 from a generalized Smoluchowski equation for Brownian motion of the actin-bead "dumbbell," and time s

224 e clamp is not fast enough to compensate the Brownian motion of the bead, interpretation or analysis

225 magnetic beads was found to be dependent on Brownian motion of the beads, suggesting a 99% chance of

226 ngly suggest that the anisotropic rotational Brownian motion of the clusters combined with short-rang

227 netic field noise produced by the rotational Brownian motion of the ensemble of bacteria.

228 gion can be described by a spring model with Brownian motion of the fragments in a harmonic potential

229 view, the work reported here indicates that Brownian motion of the hair bundle serves to enhance the

230 bution of such samples is determined via the Brownian motion of the particles, but simultaneous deter

231 tion of the spin is used to sense driven and Brownian motion of the resonator under ambient condition

232 with intersubunit motions and thus with the Brownian motion of the solvent.

233 Independent of the Brownian motion of themselves, the as-proposed isotropic

234 The Brownian motion of two particles in three dimensions ser

235 We investigated whether changes in the Brownian motion of water within tumor tissue as quantifi

236 The highly resolved Brownian motions of these particles reveal the viscoelas

237 ivity of the signal to the thermally-induced Brownian motions of water molecules and in vivo measurem

238 ents build on combining analyses of confined Brownian-motion of bacteria adhering to glass and their

239 ian motion and the diffusion coefficient for Brownian motion on both simulated and experimental data.

240 Surprisingly, lengthwise Brownian motion only partially accounts for the transloc

241 t is unlikely to be mediated by centromeres, Brownian motion or random drift and must be caused by an

242 increments that is at the core of fractional Brownian motion (or alternatively generalized Langevin e

243 distinct therapeutic-induced changes in the Brownian motion (or diffusion) of water within tumor tis

244 ng against fluctuating obstacles (fractional brownian motion) or nonergodic with a broad distribution

245 characterizing both diffusive and fractional Brownian motion overlaid by flow and analytically calcul

246 fusivity parameter ([Formula: see text]) and Brownian motion parameter (Nb) but reduced considerably

247 y reduced with greater Lewis number (Le) and Brownian motion parameter (Nb).

248 hermophoresis parameter [Formula: see text], Brownian motion parameter [Formula: see text], Lewis num

249 oltage-dependent ion channel is treated as a Brownian motion particle undergoing spatial diffusion al

250 nates-describes spread as a Brownian motion (Brownian Motion Phylogeography, BMP) in continuous space

251 In contrast, Brownian motion poorly reflects our data.

252 t for detailed study by optical methods, but Brownian motion prevents the observation of one single m

253 agreed with the diffusion coefficients from Brownian motion previously reported from correlation ana

254 forward neural network trained on fractional Brownian motion, providing a novel, accurate and efficie

255 number, thermophoresis, ion-slip parameter, Brownian motion, radiation, Eckert number, and Hall para

256 s, suggesting that it results from classical Brownian motion rather than from active motility.

257 We consider Brownian motion restricted by randomly placed and orient

258 fusion within condensates follows fractional Brownian motion resulting from viscoelastic interactions

259 can alter many colloidal properties such as Brownian motion, self-assembly, and phase behavior.

260 ion, cell pairs showed an essentially random Brownian motion, similar to the case for untreated, isol

261 amics of individual polymer chains driven by brownian motion: since individual chains can only move i

262 The ratio of Brownian-motion spectra before and after treatment was c

263 positional displacements arising from biased Brownian motion that are kinetically captured and then d

264 In particular, the Brownian motion that drives the wave function of the sys

265 ential growth of cell populations (geometric Brownian motion) that are terminated randomly around a g

266 However, in addition to thermal Brownian motion, the cytoplasm also undergoes constant a

267 viruses cannot encounter target cells due to Brownian motion, their short half-lives, and the require

268 Here, we combine Brownian motion theory, Monte Carlo simulations, and rea

269 diameter-dependent manner and adopt a rapid Brownian motion, thereby forming a porous and highly dyn

270 e oscillations are larger than expected from Brownian motion, they must result from an active process

271 ult of rapid interparticle collisions due to Brownian motion; this interpretation is consistent with

272 l or chemical systems is produced by biasing Brownian motion through cyclic chemical reactions.

273 heet domains are highly mobile and driven by Brownian motion to elicit phosphoenzyme formation and ca

274 We use Brownian motion to model genetic drift under neutrality,

275 he ribosome as a molecular machine employing Brownian motion to reach a functionally productive state

276 n external energy source (light) into biased brownian motion to transport a macroscopic cargo and do

277 nd for downstream target positioning regular Brownian motion turns out to be the advantageous search

278 Additionally, in contrast to Brownian motion typical of centrosymmetric nanoparticles

279 During centrifugation, nanoparticles undergo Brownian motion under an external field and move with di

280 in diffusion in solution can be described as Brownian motion up to physiological concentration and th

281 les by the laser, we analyzed their measured Brownian motion using, to our knowledge, a newly derived

282 tudy, a natural phenomenon called rotational Brownian motion was characterized by Janus particles and

283 Brownian motion was markedly reduced by the gel framewor

284 For short times, the ballistic regime of Brownian motion was observed, in contrast to the usual d

285 ads were injected in jellyfish ECM and their Brownian motion was recorded to determine the mechanical

286 Instead of Brownian motion, we find an activated jump diffusion mec

287 Shark movements were best approximated by Brownian motion when hunting near abundant, predictable

288 , both phases are affected by fluid drag and Brownian motion, which are themselves governed by cell g

289 ion for various surfaces, we obtain confined Brownian motion, which has direct applications to many b

290 d individuals can be modeled by resorting to brownian motion, which is applicable when long-range mov

291 escentus cells attached to a surface undergo Brownian motion while confined effectively in a harmonic

292 t by noting that the substrate, by virtue of Brownian motion, will make repeated attempts to enter th

293 hly heterogeneous and cannot be described as Brownian motion with a single diffusion coefficient.

294 By using this analysis, fractional Brownian motion with a stochastic Hurst exponent was use

295 s, strong chaos leads to diffusive behavior (Brownian motion with drift) and weak chaos leads to supe

296 lutions of the many-body master equation for Brownian motion with motorized kicking we obtain a close

297 o enhanced diffusion far beyond the level of Brownian motion with possible influences on the spatial

298 sion (subdiffusion) that converges back to a Brownian motion with reduced diffusion coefficient at lo

299 Thermoenergy (Brownian motion) would suffice for substrate translocati

300 Granular materials do not perform Brownian motion, yet diffusion can be observed in such s