ライフサイエンスコーパス: inertial

1 whereas neurons that represented net gravito-inertial acceleration did not show choice probabilities.

2 The inertial acceleration of the electron collective mass is

3 estibular cue to heading is the direction of inertial acceleration that accompanies transient linear

4 ed linear accelerations in absence of a true inertial acceleration.

5 t tangential neurons function as a broadband inertial accelerometer, processing utricular acceleratio

6 that have not been discussed before for both inertial and accelerated dynamics, and chart perspective

7 initially occurs in an inertial regime where inertial and capillary forces balance.

8 d their motion is governed by the balance of inertial and viscous forces.

9 stance, by decoupling motor output from both inertial and visual feedback.

10 her that characterizes the relative thermal, inertial, and capillary dynamics of the drop.

11 mined by the relative importance of viscous, inertial, and capillary forces.

12 plitude of the inertial component (extent of inertial angular displacement) depends strongly on the s

13 s no longer a significant determinant of the inertial angular motion.

14 k could advance our general understanding of inertial appendage use in locomotion.

15 Three ingredients are involved: a soluto-inertial "beacon" designed to emit a steady flux of solu

16 chemical dispersion, vertical currents, and inertial buoyancy motion on oil rise velocities.

17 coustic emissions during treatment confirmed inertial cavitation as the mechanism responsible for enh

18 sustains stable cavitation while suppressing inertial cavitation behavior was designed and validated

19 in three hours can be achieved by optimising inertial cavitation dose during ultrasonication.

20 ed with, and therefore can be controlled by, inertial cavitation dose.

21 The inertial cavitation events driving this release could be

22 rovided that the exposure created sufficient inertial cavitation events, as characterised by violent

23 We found that inertial cavitation generated the highest rate of membra

24 Ultrasound-generated non-inertial cavitation has the ability to potentiate the th

25 To induce localized inertial cavitation in pancreatic tumors, pulsed high-in

26 en AdEHE2F-Luc was delivered via the vessel, inertial cavitation increased transgene expression in tu

27 demonstrates that measurement and control of inertial cavitation is critical in optimising the high y

28 Furthermore, inertial cavitation is shown to preferentially exfoliate

29 Inertial cavitation mediated by ultrasound has been prev

30 achieved using nanodroplets without inducing inertial cavitation or compromising safety.

31 cinoma as model cell line, that unseeded non-inertial cavitation potentiates the cytotoxicity of doxo

32 We demonstrate that inertial cavitation preferentially exfoliates larger fla

33 treatment with doxorubicin and unseeded non-inertial cavitation significantly reduced cell viability

34 /cm(2)), sonoporation usually occurs through inertial cavitation that accompanies explosive growth an

35 hanisms of permeability-enhancing stable and inertial cavitation were investigated by passively monit

36 An electrochemical technique that can detect inertial cavitation within an ultrasonic reactor is repo

37 bility of wideband emission (a signature for inertial cavitation) was than 1%.

38 unction of tumor reperfusion time to sustain inertial cavitation, a type of microbubble activity, thr

39 In the presence of inertial cavitation, AdEHE2F-Luc distribution was greatl

40 histotripsy, (b) tissue permeabilization via inertial cavitation, and (c) mild (<10 degrees C) heatin

41 Its fundamental mechanism, inertial cavitation, is poorly understood and often igno

42 either broadband emissions, associated with inertial cavitation, or ultraharmonic emissions, associa

43 ate unseeded (without nucleation agents) non-inertial cavitation, where cavitation is initiated, moni

44 y be related to capillary damage produced by inertial cavitation, which might have resulted in excess

45 clei for the initiation of an event known as inertial cavitation.

46 cavitation, coalescence and translation, and inertial cavitation.

47 l sorting (aFACS) system by combining elasto-inertial cell focusing and highly focused traveling surf

48 ntinuously fabricated using surfactant-free, inertial centralisation, and ultrafast polymerisation, i

49 vigation, and autonomic responses to gravito-inertial changes.

50 ful to improve positioning of particles with inertial channels with multiple equilibrium positions.

51 and packing fraction are still elusive when inertial, cohesive and viscous interactions occur betwee

52 r condensation in a laminar flow, permitting inertial collection into the microchip sample reservoir.

53 65 degrees C shows that the amplitude of the inertial component (extent of inertial angular displacem

54 The inertial component becomes frequency-independent at low

55 Using inertial confinement fusion (ICF) as a test-bed problem,

56 Recent progress towards demonstrating inertial confinement fusion (ICF) ignition at the Nation

57 mixing of contaminant mass into the fuel in inertial confinement fusion (ICF) implosions is a primar

58 ies can occur in very diverse settings, from inertial confinement fusion (ICF) implosions over spatia

59 ecause of applications to planetary science, inertial confinement fusion and fundamental physics, its

60 Laser-driven, inertial confinement fusion depends upon the interaction

61 re used in the modelling of white dwarfs and inertial confinement fusion experiments(7,8), and we pre

62 is a promising approach for high-energy-gain inertial confinement fusion in the laboratory.

63 of ions in dense plasmas is a key process in inertial confinement fusion that determines the alpha-pa

64 f the giant planets; it is also relevant for inertial confinement fusion.

65 to those studying planetary astrophysics and inertial confinement fusion.

66 interiors of giant planets, in stars, and in inertial-confinement fusion experiments.

67 at temperatures in excess of 10(6) kelvin on inertial-confinement timescales using an X-ray free-elec

68 ities studying laser-plasma-acceleration and inertial-confinement-fusion, but also for application to

69 Leaping lizards show that inertial control of body attitude can advance our unders

70 As vestibular signals only provide inertial cues of self-motion (e.g., velocity, degrees /s

71 ation of somatosensory and vestibular (i.e., inertial) cues.

72 ch as internal tides and atmospheric-related inertial currents, rather than day-night rhythms.

73 tatively reflect the correlation between the inertial decay and the OD stretching frequency.

74 s a correlation between the amplitude of the inertial decay and the strength of the O-D O hydrogen bo

75 he experimentally measured amplitudes of the inertial decays yield estimates of the characteristic fr

76 The observed near-zero and positive inertial defect clearly indicates that the molecular str

77 7(5), and C = 2749.1281(4) MHz, yielding the inertial defect Delta(0) = 0.02 amu x A(2) for the groun

78 More surprisingly, the elasto-inertial deflection of small particles can be even great

79 Interestingly, the elasto-inertial deflection of the peanut particles can be eithe

80 rrelation for the particle collection due to inertial deposition is proposed and embedded in a hetero

81 a crystalline array of molecular rotors with inertial diffusional rotation at the nanoscale, characte

82 olecular dynamics simulations, indicate that inertial diffusional rotation is characterized by a broa

83 on of incident femtosecond laser pulses into inertial displacement of a domain wall in a ferromagneti

84 ns, capable of sophisticated aerodynamic and inertial dynamics not previously observed in other flyin

85 tial return to previously visited interests, inertial effect, and exploration of new interests.

86 le response of BC nanopaper is attributed to inertial effect, in which some of the curled BC nanofibr

87 Inertial effects do not result in preferential concentra

88 and the interplay of damping, weakening and inertial effects in bulk metallic glasses have strikingl

89 the actuation speed and a regime governed by inertial effects in which high-speed actuation is possib

90 f the chloro- and bromo-complexes shows that inertial effects of the ligand motion have a greater eff

91 tead, the walker relies on gravitational and inertial effects to propel itself forward, exhibiting a

92 By taking advantage of inertial effects we demonstrate controllable self-assemb

93 wn "tubular pinch effect," which arises from inertial effects.

94 produce force to move the body; the body has inertial, elastic, and damping properties that may aid o

95 of CSCs via SdFFF using the hyperlayer mode (inertial elution mode for micrometer-sized species), we

96 kilometers account for more than 65% of near-inertial energy flux into the North Pacific basin and 55

97 dy activities causing enhanced downward near-inertial energy flux than earlier findings.

98 be a key region for the penetration of near-inertial energy into the deep ocean and a hotspot for th

99 uzzle where and through which route the near-inertial energy penetrates into the deep ocean.

100 This developed elasto-inertial exosome sorting technique may provide a promisi

101 uence of vestibular input, uncontaminated by inertial factors.

102 We investigate the inertial flow deformations around a library of single cy

103 shaped along the flow axis by software-aided inertial flow engineering.

104 er particles based on two coupled processes: inertial flow shaping and ultraviolet (UV) light polymer

105 ydraulic applications concerned with shallow inertial flows.

106 the bioluminescence signal, corresponding to inertial fluctuations.

107 hip uses deterministic lateral displacement, inertial focusing and magnetophoresis to sort up to 10(7

108 outlets with fluidic resistors, allowing for inertial focusing and ordering, enhancement of the diffe

109 ocompatible polymer was presented for elasto-inertial focusing and sorting of submicron particles and

110 ve evaluated the performance of these staged inertial focusing channels using standard flow cytometry

111 ost notably, our analysis indicates that the inertial focusing channels virtually eliminated particle

112 e utilize the high-speed phenomenon known as inertial focusing combined with hydraulic resistance con

113 f the shape-activated differences in lateral inertial focusing dynamic equilibrium positions, E. grac

114 Microfluidic inertial focusing has been demonstrated to be an effecti

115 Based on inertial focusing in spiral microfluidic channels, I-SEL

116 s suggest a potentially significant role for inertial focusing in the development of inexpensive flow

117 Inertial focusing is a microfluidic based separation and

118 em to enrich the microparticles based on the inertial focusing mechanism was tested.

119 he prototype flow cytometer equipped with an inertial focusing microchannel matched the resolution pr

120 coelastic carrier fluids for enhanced elasto-inertial focusing of biological species within straight,

121 The system is based upon differential inertial focusing of particles of varying sizes and allo

122 d fluidic resistance, useful for lower power inertial focusing or separation.

123 Under the conditions studied, inertial focusing organized large particles into an annu

124 annels presumably modifies these equilibrium inertial focusing positions, because of the secondary fl

125 Because inertial focusing produces well-defined lateral equilibr

126 hese devices are serially integrated with an inertial focusing system to line up all nucleated cells

127 volume processing with stacked and cascaded inertial focusing systems, allowing for separation and c

128 The method uses inertial focusing to uniformly deliver cells to a stretc

129 By leveraging label-free, inertial-focusing microfluidic approaches in retrieving

130 the channel Reynolds number (Re(C)) and the inertial force ratio, which is a new dimensionless param

131 Cells are subject to inertial forces and to active forces that try to align t

132 In typical geodynamo models, viscous and inertial forces are not much smaller than the Coriolis f

133 f jet propulsion is still in the range where inertial forces are significant.

134 f very similar strength, whereas viscous and inertial forces are smaller by a factor of at least 20 i

135 ey are believed to detect Coriolis and other inertial forces associated with body rotation during fli

136 The detection of gravito-inertial forces by the otolith system is essential for o

137 one-conducted (BC) route of hearing, through inertial forces exerted by the middle ear and cochlear f

138 thins, viscous forces in the former case and inertial forces in the latter become important, and theo

139 nolds number flows, particles may experience inertial forces that result in trans-streamline movement

140 ompetition between surface tension and fluid inertial forces, and harnesses the naturally occurring c

141 olis) with only minute roles for viscous and inertial forces, dynamo simulations must use viscosity v

142 it information at a high rate about numerous inertial forces, including Coriolis forces.

143 channel walls and the domination of complex inertial forces.

144 ened effective potential is generated in the inertial frame of an ion traversing the device with appr

145 e demonstrate that no treadmill serves as an inertial frame of reference.

146 tation of the black hole's accretion disk or inertial-frame-dragging ergosphere.

147 ncounter, and vortexes, which twist adjacent inertial frames relative to each other.

148 ly low vertical vorticity close to the local inertial frequency and important strain rates at the per

149 ity (NIF) has sparked wide interest in Laser Inertial Fusion Energy (LIFE) for carbon-free large-scal

150 ense matter physics, planetary sciences, and inertial fusion energy research.

151 specification, polymer capsules, to produce inertial fusion energy targets, were continuously fabric

152 A distinctive way of quantitatively imaging inertial fusion implosions has resulted in the character

153 for beam velocities typically encountered in inertial fusion.

154 zation of critical aspects of indirect-drive inertial fusion.

155 atment is crucial for most astrophysical and inertial-fusion applications, where the case of plasma m

156 Our novel motor controller mimicked in vivo inertial/gravitational loading experienced by muscles du

157 not only stabilize the lovebirds' visual and inertial head orientations by compensating low-frequency

158 inal adhesion on ocular hemorrhage caused by inertial head rotations.

159 alyte size detectable through nanomechanical inertial imaging is not limited by wavelength-dependent

160 We validate this method for inertial imaging, using both experimental measurements o

161 ynamic particle size distributions (APSD) by inertial impaction has been developed.

162 rom diethyl zinc and oxygen and deposited by inertial impaction onto a variety of substrates.

163 ondiffusion limited sampling method based on inertial impaction.

164 When a crystal nucleates and grows, its inertial impedance is considered along with a Kelvin-Voi

165 We postulate that gravito-inertial information is used to tune visuomotor response

166 ady flame convection governed by buoyant and inertial interaction advances both theory and the physic

167 We demonstrate soluto-inertial interactions that extend for nearly half a mill

168 to the shear variance of wind-generated near-inertial internal waves with the diapycnal diffusivity 6

169 ing primarily through the generation of near-inertial internal waves.

170 tic flux, predominantly at 1- to 10-electron inertial length scale, intense electrical current sheets

171 shape dependence of the flow-induced elasto-inertial lift (and hence the cross-stream migration) in

172 lay of the repulsive viscous interaction and inertial lift also allow us to design and implement micr

173 s unique channel design allows us to enhance inertial lift force at the microsquare zone and produce

174 The inertial lift force comes into effect at relatively high

175 We demonstrate that the flow-induced inertial lift force in microchannels can be exploited to

176 of an array of islands that exert a passive inertial lift force on proximate cells, thus enabling ge

177 anism for the dynamic self-assembly process; inertial lift forces and a parabolic flow field act toge

178 al solution exchange (RInSE), which utilizes inertial lift forces at finite Reynolds number and high

179 murine adrenal glands utilizing hydrodynamic inertial lift forces that single cells and multicellular

180 interaction of the secondary flow field with inertial lift forces to create complex sets of particle

181 lutions via a combined action of elastic and inertial lift forces, which we term elasto-inertial pinc

182 less parameter that is based on the ratio of inertial lift to drag forces from the secondary flow.

183 fluidic actuation principles: the pulse-free inertial liquid propulsion provided by centrifugal micro

184 This theory predicts, for systems without inertial load, that elastic load enhances positive shift

185 Inertial loading of a hair bundle by the tectorial membr

186 In inertial loading, frequency shifts are negative and prop

187 on in tremor frequency produced by adding an inertial mass to the limb has usually been taken as a me

188 ts and numerical simulations, to analyse the inertial mass, position of adsorption and the size and s

189 s on the ratio between the gravitational and inertial masses of the antihydrogen do not rule out a re

190 the difference between the gravitational and inertial masses of the positron (antielectron) from the

191 Combining MMG with inertial measurement unit (IMU) data enabled segmentatio

192 earing a mobile eye tracker equipped with an inertial measurement unit and a 3D stereo camera.

193 tegrates a high-sensitivity image sensor, an inertial measurement unit and an LED driver for an exter

194 ctromyographic recordings, and a new digital inertial measurement unit to quantify body kinematics, r

195 Some spheres are embedded with small inertial measurement units to measure the acceleration e

196 ation of Global Positioning System (GPS) and inertial measurement units, to capture the locomotor dyn

197 paper, we present a novel design of a spiral inertial microfluidic (trapezoidal cross-section) sorter

198 is of sorting microparticles and cells in an inertial microfluidic device.

199 the first step toward designing stretchable inertial microfluidic devices that can be implemented fo

200 multiple affinity-capture microbeads and an inertial microfluidic particle sorter device.

201 work, we present a new channel design for an inertial microfluidic sorting device by embedding micros

202 we report the development and testing of an inertial microfluidic system for the label-free isolatio

203 tions using closed-loop separation of spiral inertial microfluidics (C-sep).

204 Further, we show that high-throughput inertial microfluidics enables efficient sorting of comm

205 Inertial microfluidics has been proven to be a powerful

206 Inertial microfluidics has recently drawn wide attention

207 However, the current obstacle of inertial microfluidics in biological applications is the

208 Inertial microfluidics is a promising approach for parti

209 The developed inertial microfluidics technology enables single-step ne

210 filtration system by massively parallelizing inertial microfluidics to achieve a macroscopic volume p

211 roughput, and continuous technique utilizing inertial microfluidics to separate E. gracilis by a key

212 This paper presents a novel MEMS-based inertial microswitch design with multi-directional compa

213 The MEMS inertial microswitch micro-fabricated by surface microma

214 ponse process indicates that in the designed inertial microswitch the proof mass weight G, the whole

215 Using an inertial model, we estimated that carrying a load on the

216 by presenting optic flow (visual condition), inertial motion (vestibular condition), or a congruent c

217 are found associated with a long-term solar inertial motion about the barycenter of the solar system

218 g discrimination task solely on the basis of inertial motion cues.

219 urons are almost universally unresponsive to inertial motion in the absence of optic flow.

220 olves re-orienting the spray axis to harness inertial motion of particulates and has been developed u

221 que V6 neurons in response to optic flow and inertial motion stimuli.

222 edominantly eye-centered, whereas tuning for inertial motion was intermediate but closer to head-cent

223 rious time scales were observed including an inertial motion, a restricted wobbling motion of approxi

224 nonlinearity in the neural representation of inertial motion.

225 heading) in response to both optic flow and inertial motion.

226 The wind work on oceanic near-inertial motions is suggested to play an important role

227 rs with touch-sensitive screens and embedded inertial movement sensors to record the movement kinemat

228 tom interferometers for applications such as inertial navigation and gravity mapping.

229 ng general relativity to portable clocks for inertial navigation systems and relativistic geodesy.

230 is dimensionless parameter, as a generalized inertial number, describes the texture variables such as

231 s a sharp drop at very short times caused by inertial orientational motion, followed by a much slower

232 PSPP measurements observed only inertial orientational relaxation.

233 control of a virtual arm with representative inertial parameters using real-time neural control of to

234 mals, such as body contours, muscle bulk, or inertial parameters, it is also useful for non-invasive

235 microfluidic sorting device utilizes elasto-inertial particle focusing to align cells in a single fi

236 An Inertial-Particle, Coupled Eulerian-Lagrangian Closure m

237 viding time series on the length of detected inertial periodicity.

238 ifficult, and, at microwave frequencies, the inertial phase delay has been buried under electron scat

239 ured as microwave ground together enable the inertial phase delay to be resolved from the electron sc

240 d inertial lift forces, which we term elasto-inertial pinched flow fractionation (eiPFF).

241 or equivalent spherical diameter) via elasto-inertial pinched flow fractionation (eiPFF).

242 on affinity, dielectrophoretic mobility, and inertial properties of cells.

243 control, active muscle, and system material/inertial properties.

244 ronous release, the model predicts a delayed inertial protein unbinding associated with the SNARE com

245 s P(tau) above a positive threshold Q in the inertial range is described by a universal q- exponentia

246 the energy passes although a nondissipative inertial range until it reaches a small enough scale tha

247 hout relying on the existence of an extended inertial range.

248 Thus, most CSs correlated best with inertial rather than net linear acceleration.

249 eletal changes and that large strains in the inertial regime cannot resolve changes to the actin cyto

250 unsteady inertial regime for dogs and steady inertial regime for cats.

251 p in different physical regimes: an unsteady inertial regime for dogs and steady inertial regime for

252 ous liquids, thinning initially occurs in an inertial regime where inertial and capillary forces bala

253 just two dynamical regimes: a viscous and an inertial regime with a cross-over region between them.

254 When designed to operate in the inertial regime, electrohydraulic actuators will enable

255 In the inertial regime, we follow cellular response from (visco

256 hatch from the egg already swimming in this inertial regime.

257 ape rate boost extends into the low-friction inertial regime.

258 sts between theory and experiment, the large inertial relaxation predicted by simulations but clearly

259 -1) with a 1230 cm(-1) contribution from the inertial response of water.

260 ce, where energy cannot be dissipated in the inertial-scale range and is, therefore, cascaded from la

261 We show that adding vestibular (inertial) self-motion signals to optic flow almost compl

262 both measurements in fundamental physics and inertial sensing applications.

263 associated with navigation, positioning and inertial sensing(1).

264 broad commercial applications for timing and inertial sensing.

265 llow the vestibular system to function as an inertial sensor and contribute critically to both naviga

266 They wore miniature wrist wireless inertial sensors (actigraphs) throughout the admission.

267 Additionally, inertial sensors based on cold atoms could reach better

268 eociliary bundles in the inner ear, serve as inertial sensors for balance.

269 ioning System (GPS) and 6-degrees-of-freedom inertial sensors to show that pigeons (1) maintain power

270 Applications include atomic clocks, inertial sensors, and fundamental physics experiments su

271 l application in devices such as magnetic or inertial sensors.

272 ignals collected using non-invasive wearable inertial sensors.

273 esign of high-accuracy timing references and inertial sensors.

274 separation mechanism called non-equilibrium inertial separation array (NISA).

275 xploits a swirling flow to enable the use of inertial separation to prescribe different fates for ele

276 particles across fluid streams termed rapid inertial solution exchange (RInSE), which utilizes inert

277 reaction (qPCR) analysis, we found that our inertial sorting approach has nearly 3-fold improvement

278 higher than 92%, demonstrating a size-based inertial sorting at submicron resolution (i.e., 0.5 mum)

279 The present inertial sorting at submicron resolution provides a simp

280 This inertial sorting device has successfully separated 5.5 m

281 We further applied this inertial sorting device to purify Candida species from w

282 oduce a novel cell retention device based on inertial sorting for perfusion culture of suspended mamm

283 vity improvement obtained via vortex-induced inertial sorting of electrosprayed droplets/ions: one po

284 blood cells for accurate molecular analysis, inertial sorting of micron-sized biological particles wi

285 he processing demands produced by visual and inertial stimulation.

286 Inertial swimmers use flexural movements to push water a

287 We used high-resolution GPS and inertial technology to record 1,119 high-speed chases of

288 We used high-resolution GPS and inertial technology to record fine-scale movement of all

289 hich results in the introduction of an extra inertial term accounting for structural differences.

290 the characteristic viscous time scale to the inertial time scale of acceleration of the wind stream i

291 Elasto-inertial turbulence is found to occur at much lower Reyn

292 ale turbulence and any relation to classical inertial turbulence remains obscure.

293 lence is an innate phenomenon, distinct from inertial turbulence, that spontaneously occurs at low Re

294 different type of disordered motion, elasto-inertial turbulence.

295 the filament approaches breakup in the final inertial-viscous regime where all three forces balance.

296 sient regimes, thereby delaying onset of the inertial-viscous regime.

297 response of the tropical mixed layer to near-inertial waves (NIWs) has only rarely been observed.

298 erating two distinct flow regimes (shear and inertial) which can expose subtle mechanical properties

299 is estimated that 45%-62% of the local near-inertial wind work 4.5 x 10(-3) Wm(-2) radiates into the

300 ested to be maintained by the energetic near-inertial wind work and strong eddy activities causing en